JPH09156160A - Imaging method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform printing with no trouble even when print information unrelated to the imaging order is mixed by imaging a color coded data while converting the color code into a color component corresponding to each imaging order. SOLUTION: Dot data read out from image memories 8, 21 are superposed through an OR gate 7 and inputted to a line butter 6 which then outputs a dot data to a laser light modulation circuit 5 for driving a laser 4 depending on the dot data. A laser light modulated depending on the dot data is directed to a rotary polygon mirror 3 for scanning and focused through a lens 2 onto a photosensitive drum 1 thus forming an electrostatic latent image. The step for forming a print image is similar to that for conventional laser beam printer and four kinds of developers can be used selectively for Y, M, C and Bk (black).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming method for a color printer, and more particularly to a color printer which transmits color information of print data sent from a host computer to the printer side for printing. Image forming method.

[0002]

2. Description of the Related Art To transfer color information from a host computer to a printer side in a color printer, the host computer creates color information that is unique to the color printer and prints the color information according to the order of printing the color information. It was sent to the printer side in sequence.

[0003]

However, in the above description, the host computer must be familiar with the printing phase on the printer side, and send the color data to the printer side in an order that matches the color data printing phase. I have to do it.

The present invention has been made in consideration of the above points, and its purpose is to include (1) the printer information in the color print information sent from the host computer to the printer side. Even if the print information corresponding to the image forming order and (2) the print information with the color code irrelevant to the image forming order of the printer are mixed, the printing can be performed without any trouble. Another object of the present invention is to provide an image forming method for a color printer having excellent operability.

[0005]

In order to achieve such an object, the image forming method of the present invention uses image forming data sent from a host computer to a printer side through a single channel to form a plurality of types of color. In a color printer image forming method of forming a single color or an overlaid image according to a predetermined image forming order using a material, an image is formed in the image forming data sent from the host computer to the printer side and separated. When both the image forming data corresponding to the image forming order and the image forming data with the color code irrelevant to the image forming order are given, the data corresponding to the image forming order is processed according to the respective image forming order. Image formation is performed, and for the image formation data with a color code, the color code of the color corresponding to each of the image formation order is set. It is converted into a separating and executes the image formation.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the drawings.

FIG. 3 is a block diagram of a color image recording apparatus showing an entire embodiment of the present invention. In the illustrated color image recording apparatus, a character code string signal as shown in FIG. 4 is used as the character image data 101, and R (red), G (green), B as shown in FIG. 5 is used as the color image data.
The (blue) color identification signal 104, the vertical and horizontal synchronization signals 106V and 106H, and the image signal 105 are supplied from an external device such as a host computer. Further, the image trimming position designating signals 102, 103, 107, 108
Is also provided from an external device. The numerical values on each line in FIG. 3 represent the number of bits. Also, 12,
Reference numeral 29 is an interface circuit for inputting character image data and halftone image data to the character code decoder 11 and the image buffer memory 28, respectively.

FIG. 4 shows a character image data string signal, which includes the character string data C ₁₀ , C ₁₁ , C _12, ... In the first row following the leading identification code ITOP of one image. Also,
The RET code is inserted after the last character of each line. Therefore, when the RET code is detected on the receiving side (that is, the color image recording apparatus side), a line feed is performed.

In FIG. 4, R ₁ is the RET code on the first line and R ₂ is the RET code on the second line. Next to the last line in the character image, the end code IE of the character image
ND is inserted to end the character image data. In this color image recording apparatus, the end of the character image is identified by receiving this IEND code.

Character image data 1 supplied as described above
01 is stored in the character code buffer 10 for one screen. At this time, the above-mentioned special code (for example, ITOP code, RET code, IEND code) is decoded by the character code decoder 11, and the storage start / line feed command signal 109 and the storage end signal 110 for storing the character image are transmitted. It In response to the storage start / line feed command signal 109, the write address generator 19 sequentially generates addresses.

FIG. 6 shows an example of the character screen thus stored. Here, each character A, B,... A, b,
c, ... Are represented by an 8-bit ASCII code, for example. Since this color image recording apparatus employs a laser beam system for expressing a reproduced image as a dot image, it is necessary to convert the above-mentioned character code string into a dot form. Therefore, in the present embodiment, the dot conversion is performed using the character generator 9. The normal character generator is provided with a character portion CP and a margin portion WP as shown in FIG. Therefore, for example, when the character "A" is dot-converted according to the figure, the inside of the 9 × 9 pixel is as shown in FIG. An area information signal 102 indicating which area of the one-character image supplied from the external device should be printed out.
(That is, information specifying the row and column of the character code image)
Is given from an external device.

For example, in the character code image shown in FIG. 6, the print start character and end character are (m ₁ ,
When given by n ₁ ) to (m ₂ , n ₂ ), the area within the bold line shown in the figure is read from the character code buffer 10. That is, in response to the printout designation information (m ₁ , n ₁ ) and (m ₂ , n ₂ ) included in the region information signal 102, the read position designation circuit 17 and the read address generator 18 determine the read address of the designated region. Occur.

On the other hand, a designation signal 103 designates a region in the print image to which the character image region designated as described above should be printed out. The writing area for printout is given with the pixel number of the writing start position, the scanning line number (m ' ₁ , n' ₁ ) and the same number of the writing end position (m ' ₂ , n' ₂ ),
The image memory write position designating circuit 15 and the image memory address generator 14 generate a write address to the image memory 8.

The character code image in the specific area thus read out from the character code buffer 10 is converted into dot data by the character generator 9 and stored in the designated area in the image memory 8 to be printed out. . This situation is shown in FIGS. 7A and 7B.

Next, the processing of the color halftone image supplied as the density data of each color of R, G and B will be described. As shown in FIG. 5, this color halftone image has R, G, and B color identification signals 104 and vertical and horizontal synchronization signals 106V and 106V.
It is composed of H and 8-bit density data (that is, image signal) 105 for each pixel of the image. In this embodiment, the density data is sent in parallel for each pixel of 8 bits, but the density data may be sent serially. The color images are stored in the buffer memories 28-1, 28-2, 28-3 for the respective colors in accordance with the R, G, B color identification signals 104.

The synchronizing signals 106V and 106H are supplied to the storage address generator 32, and the address selector 30 supplies necessary addresses to the image buffer memories 28-1, 28-2 and 28-3. Thus, each color image is stored in the image buffer memory 28-1, 28.
It is stored in each of -2 and 28-3.

After that, similarly to the case of reading from the character code buffer 10, the area of the portion to be printed out of the halftone image stored in the buffer memory is designated by the signal 107 supplied from the external device. this is,
The printout start point, the pixel number, and the scanning line number are given, and the corresponding image memories 28-1, 28-
2, 28-3 addresses are generated from the read address generator 31.

At the time of reading, the image buffer memory for yellow (Y) (stores the B signal) 28-1,
From the image buffer memory (stores G signal) 28-2 for magenta (M) and the image buffer memory (stores R signal) 28-3 for cyan (C) 28-3, the same pixel has Y, M and C components, respectively. Are read at the same time.
(Here, for example, the complements of the B, G, and R signals are taken and output as Y, M, and C signals.) The color signals thus read out are finally subjected to predetermined processing, and finally, Is stored in the image memory 21 for halftone images, and is written by a signal 108 supplied from an external device (not shown) so that the designated image area is printed out at the designated position as described above. The starting position is specified.
In response to this, the image memory write position designating circuit 2
3 and image memory address generator 22
Generates the address of the image memory 21 corresponding to the designated position. This operation is the same as in the case of the character image data described above. This state is shown in FIGS. 8C and 8D.

The image buffer memory 28-1,
The color density data for each pixel read from 28-2 and 28-3 is subjected to gamma conversion (density conversion) matching the characteristics of the color image recording apparatus in the gamma correction circuit 27,
Further, after the masking processing circuit 26 receives the masking processing well known in the field of printing technology, the UCR processing (undercolor removal processing) is further received by the UCR processing circuit 25, and then the dither processing circuit 24 receives the dither processing. The dot data (binarized data of "1" and "0") is stored in a specific position in the image memory 21 designated as described above. Here, the dither process is, as is well known, an electrical process for determining print dots to be output by comparing the density data of each image with a threshold value in order to reproduce a halftone. Further, in the present example, a process of determining a recording dot by comparing one pixel with a plurality of threshold values (for example, a process by density pattern determination) may be performed, and this process is also called dither process. Further, the dither processing circuit 24 may be composed of a memory such as a ROM, and the memory may be directly accessed using the density data as an address to perform dither processing (dither conversion).

The color image recording apparatus of the present invention sequentially forms a yellow image first, a magenta image second, a cyan image third, and a black image fourth on the photosensitive member 1. Since the full-color images are obtained by superimposing the color images on the transfer paper, the storage capacity of the image memory 21 is sufficient for one image. Then, each time an image of each color is formed on the photoconductor 1, the above-described color processing and transfer of each color density data (Y, M, C, Bk) to the image memory 21 are performed.

In order to read out the data from the image memory 8 for character images and the image memory 21 for halftone images and send them to the laser light modulation circuit 5, these image data are stored as dot data in the image memories 8 and 21, respectively. Further, the same address is assigned to the same pixel. In this embodiment, the addressing of both image memories 8 and 21 is controlled by the image memory address generator 14. That is, a read address is generated at the time when an image is stored in both the image memories 8 and 21, so that dot data of a character and a halftone image corresponding to the same pixel is transmitted.

The dot data read from the image memories 8 and 21 are superimposed by the OR gate 7 and input to the line buffer 6. Then, the dot data output from the line buffer 6 is input to the laser light modulation circuit 5, and the laser light modulation circuit responds to the dot data by the laser 4
Drive. The laser light modulated according to the dot data is scanned by the rotary polygon mirror 3 and forms an electrostatic latent image on the photosensitive drum 1 via the lens 2. The process of creating a print image is the same as in a normal laser beam printer, and four types of developing devices (none of which are shown) for Y, M, C, and Bk (black) are selectively used. Also,
A signal 113 is a horizontal synchronizing signal (BD signal) sent from the laser beam detector 40 when the laser beam is irradiated onto the laser beam detector 40.
The image data reading from 1 is performed in synchronization.

FIG. 3120 is a 4-bit signal that specifies the color of a character image. This signal may be a signal from a host computer, which is an external device, or a switch in the color image recording apparatus. Here, each bit of the 4-bit color designation signals C _{0 to} C ₃ is made to correspond to Y, M, C, and Bk in order. A character image of a desired color can be obtained by controlling the character image output by the latent image forming signal 112 of the color corresponding to the designated bit. For example, if (C ₀ , C ₁ , C ₂ , C ₃ ) = (1, ₁ , ₀ , 0), the character image is output from the Y and M latent image forming image memory 8 and the character becomes a red image. .

Normally, when a character image is combined with black Bk, the character image clearly appears in the halftone image more effectively. In this case, the color designation signal (C ₀ , C ₁ , C ₂ , C ₃ ) is ( ₀ , ₀ , ₀ , ₁ ). Similarly, image memory 2
It is also possible to obtain an image of a single color or a composite color by controlling so as to read only a desired color image when reading the halftone image from No. 1.

FIG. 8 shows an example in which the designated areas of the character image and the halftone image are individually moved and the two images are combined. That is, the region is moved with respect to each of the input images A and C, and the obtained images B and D are combined to obtain an image B + D.

FIG. 9 is a detailed diagram of the control circuit 16 shown in FIG.
The control circuit 16 includes a CPU 40 such as a microcomputer.
The input / output port 43 and the address timing generator 44, which are controlled by, are roughly divided into two parts. Reference numeral 41 is a ROM for storing the program of the CPU 40, 42 is a RAM for storing the data of the CPU 40, and 43 is an input / output port. The input / output port 43 includes a CPU 4
0 and the following signal lines controlled by the program ROM 41 are connected. First, a character buffer enable signal (hereinafter, referred to as CBE) 122 which is an enable signal for writing and reading to the character code buffer 10 and a character which is an enable signal for writing and reading to the character image memory 8. Image memory enable signal (hereinafter referred to as CME)
112, writing to the halftone image image memory 21;
Color image memory enable signal (hereinafter referred to as CLME) which is an imageable signal for reading 1
21, a character buffer address select signal (hereinafter referred to as CBAS) 123 which is an address switching signal for writing to and reading from the character code buffer 10, and a place to be a writing and reading start signal to the character code buffer 10. Character buffer read / write control signal (hereinafter referred to as CBRWC) 124, a character image memory read / write control signal (hereinafter referred to as CMRWC) which is a start signal for writing to the character image memory 8 and reading from the image memories 8 and 21. 125), and a signal line for transmitting a color image memory write control signal (hereinafter referred to as CLMWC) 126, which is a write start signal to the image memory 21 for halftone images. . Each of the above signals is output from the output port. When the memory enable signal becomes "1", reading or writing from the memory becomes possible. Further, at the input port, a color designation signal 120 for designating the color of the character image to be printed, a storage end signal 110 for one page which is a detection signal of the end code IEND for one page of the character code, and a printing form (for example, (Generally, it is only a character image, it is a combination of a character image and a halftone image, print start or print stop, etc.)
A print control signal (command) 127 for controlling the printing is input. Further, the address timing generation circuit 44
Character code read timing signal (hereinafter CCRT)
Called. ) 129 and a character dot timing signal (hereinafter referred to as CDWT) 130, and CCRT1
29 is used as a count signal and a read timing signal of the address generation counter in the read address generator 18, and the CDWT 130 is used as a count signal and a timing signal for writing or reading to the address generation counter in the image memory address generator 14. CCRT129 and CDWT
130 are input to the address generators 18 and 14, respectively (not shown in FIG. 3). Transfer of image data (for example, character code image or halftone color image), storage in memory, control of printout, etc. are all controlled by C in the control circuit 16.
The PU 40 performs this according to a data control command given from an external device on the host side. The data control command is shown in FIG.
As shown in 0, a command to print out a character image or a color image, and an external device as a host,
And an image data transfer start command. The operation of the CPU 40 after receiving the data control command is shown in FIG.
This will be described according to the flowchart of FIG.

First, in steps S200 to S204, a data control command (see FIG. 10) is read, and processes A to E corresponding to each command are performed. Command = 001
In (step S200), since the command is a character print command, the process proceeds to process A, and CME (character image memory enable) 112 = "1" (step S20).
As 5), the CLM is used to make the character image memory 8 accessible and the color halftone image memory 21 inaccessible (disabled).
It is assumed that E121 = "0" (step S206). Then, CMRWC125 = “1” (step S207) is set to generate an address to the character image memory 8. Further, the address generation circuit 14 includes the image memory 8
In this case, the memory read mode is designated because it is shared during writing and reading. By the above operation, the character image data is read at the image transfer clock (not shown) in synchronization with the image read synchronization signal 113.
This image data is subjected to synchronous matching with the printer in the line buffer 6, modulates the laser light, and contributes to image formation. Also, in step S201, command = 010
If it is determined that the printout is for the halftone image only, the process B is performed.

In process B, the CLM is executed in step S208.
E121 = “1” and the color halftone image memory 21
In an accessible state, and the CME is
112 = "0" is set to make the character image memory 8 inaccessible. Then, CMRWC = “1” to generate an address to the color halftone image memory 21.
(Step S210). Then, as in the process A, the address generation circuit 14 is designated to the memory read mode.

Further, in the composite printout of the character image and the halftone image (command = 011, step S202, process C), both the character image memory 8 and the color halftone image memory 21 are enabled, and the image output is performed. (Steps S211 to S213). In the present embodiment, the character image can be printed out in a predetermined color of Y, M, C, Bk, or a color obtained by a combination thereof, but this color designation is sent from an external device such as a host computer. Given by the color designation signal 120, at the time of printing out (developing) a predetermined color of the color printer, the process A or C is performed to print out the desired color.

Next, the image transfer start command will be described. An external device such as a host computer needs to send either a character code transfer start command or a color image transfer start command before transferring image data to the color image recording apparatus. For example, in the case of a character code, when command = 101 is received by this apparatus, processing D is performed from step S203. That is, CBE (character buffer enable) = "1" (step S214), CBRWC (character buffer read / line control) = "1" (step S21)
5), the write address is given to the character code buffer 10, and the character code sent from the external device such as the host one by one is the character code buffer 1.
0 are sequentially stored. At this time, CBAS (character buffer address select) sent from the CPU 40
The signal causes the address selection circuit 20 to select a write address as an address. When the transfer of the character code is completed, the character code decoder detects the IEND code inserted at the end of the above-mentioned one page, and sends the character code transfer end signal 110 to the CPU 40 to notify the end of the transfer of the character code data.

Next, in the case of color halftone image transfer, it is determined in step S204 and the process E is entered. In process E, the image buffer memory enable signal (CLBE) 134 is set so that the image buffer memory of the color designated by the color identification signal 104 of the transferred color image can be accessed.
Is output to the memory 28 (steps S217 to S22).
1) Store each color image data in a predetermined image buffer memory. At the time of writing, an address select signal (referred to as CLBAS) 132 is output from the CPU so that a write address is given to the image buffer memory. CLBAS is input to the address selection circuit 30 (not shown in FIG. 3). The write address is given in synchronization with the vertical and horizontal sync signals 106V and 106H, and when the storage of a predetermined number of lines (4752 lines in this embodiment) is completed, the write address generator 30 causes the storage end signal CIEND 133 (not shown in FIG. 3). Output),
Notify CPU40.

After the character code and the color halftone image are respectively stored in the buffer memories 10 and 28 as described above, each image data is transferred to the image memories 8 and 21 of the next stage after undergoing a predetermined process.

First, the reading from the character code buffer 10 and the writing to the image memory 8 are performed. In the character code buffer 10, the read address generating circuit 18 is used.
Reading is performed according to the address output from.
At this time, the read position designating circuit 17 designates which area within one page should be printed out. For example, in FIG.
In A, by setting the upper left address (Cx ₁ , Cy ₁ ) and the lower right address (Cx ₂ , Cy ₂ ) in the read position designating circuit 17, only the area shown in the figure (area surrounded by a rectangle) should be read. The address is generated and provided to the character code buffer 10. Similarly, in the case of a color image, in FIG.
Upper left address (CLx ₁ , CLy ₁ ), lower right address (C
Lx ₂ , CLy ₂ ) is set in the read position designating circuit 33 so that only the area shown in FIG. 8C is read.
A read address is generated. Next, when the read image data is stored in the image memories 8 and 21, it is necessary to set the writing position designation circuit 15 or 23 at which position on the copy paper the read image should be printed. For example, in FIG. 8B, the upper left address (CX ₁ , C
Y ₁ ) and the lower right address (CX ₂ , CY ₂ ) are set in the write position designating circuit 15 to transfer the read character image to the position shown in FIG. 8B. FIG. 8D
Then the address (CLX ₁ , CLY ₁ ), (CLX ₂ , CL
By setting Y ₂ ) in the writing position designating circuit 23, the read color halftone image is transferred to the position shown in FIG. 8D. Therefore, when these transferred image data are combined, an image laid out as shown in FIG. 8B + D is formed.

The addresses for designating the above-mentioned area are the signals 102, 103, 107 from the external device,
108.

FIG. 11 shows the data input section of this apparatus. In this apparatus, since the image data 100 (character image data and color halftone image data) transferred from an external device such as a host is supplied through the interface circuit 45 by a cable of one system, it is internally supplied. Are separated into two data processing systems (a character code processing system and a color halftone image processing system). Prior to the transfer, the CPU 40 causes the data reselect DS signal 14 to be transmitted by a character code transfer start command or a color image transfer command sent from an external device such as a host.
0 is sent to the data selector 46 to switch the data processing system. Therefore, even with various types of data, such as compressed code strings of image data, other codes, or data of different types such as command strings, a data identification signal (data control command as shown in FIG. 11 in this embodiment) and data By having a switching circuit such as a selector, transmission / reception can be performed using one system of data line. For example, if the form as shown in FIG. 13 is adopted, it is possible to receive the compression code of the facsimile and synthesize the character image, the color halftone image and the facsimile image. That is, if the FAX code identification command is added to the command shown in FIG.
U40 receives the identification command and sends a select signal DS to the data selector 250 prior to sending the compressed code.
255 to output a facsimile compression code such as M
H code can be selected and received. Then, the MH code is stored in the buffer memory 251 in the same manner as the character image data and the color halftone image. MH
After the code is stored, the code is read out, decoded by the MH decoder circuit 252, expanded into a dot image, and stored in the next-stage FAX image memory 253. On this occasion,
It is also possible to designate an area and print out only the specific area or to the specific area by the same method as described above. Finally, by outputting the dot data to the above-mentioned printer through, for example, the OR gate 254, the above-mentioned character image, color halftone image and facsimile image can be combined, and an image as shown in FIG. 14 can be obtained. .
In FIG. 14, A is a character image area, B is a color halftone image area, and C is a facsimile image area.

In FIG. 13, the circuit for processing the character code and the circuit for processing the halftone image data are the same as those in FIG.

FIG. 15 is for explaining the third embodiment. It should be noted that components having the same functions as those in FIG. 3 are designated by the same reference numerals and the description thereof will be omitted. Therefore, here, the part different from the circuit of FIG. 3 will be mainly described.

In the figure, reference numerals 335 and 336 denote dark tone extraction circuits and dark tone memories for storing a dark tone portion. Dark tone extraction circuit 335
Are the comparison circuits 342, 343, 3 as shown in FIG.
44, switches 346, 347, 348 and the like. The switches 346, 347, 348 set the amount of each density component of Y (yellow), M (magenta), and C (cyan) that should be discriminated as a dark tone. Comparison circuit 342,3
Reference numerals 43 and 344 compare the Y, M, and C components of the input image density with the set values set by the switches 346, 347, and 348, and when the input image density component amount exceeds the set value, " 1 ”is output. When the input image densities of all Y, M, and C exceed the set values, the comparison circuits 342, 343,
Since the outputs 342-1, 343-1, 344-1 of 344 are all "1", this pixel is regarded as a dark portion,
“1” is stored in the dark tone memory 336 shown in FIG.
Is stored. At this time, the data writing to the dark tone memory is performed in accordance with the address 118 generated by the address generation circuit 22 by being addressed from the outside not shown in the same manner as the storage in the image memory 21 for the halftone image. Therefore, the dark tone memory 33
6 has the same capacity as the image memory 21. Further, in this configuration, the switches 346, 34 of FIG.
By changing the setting value of 7,348, the color regarded as dark tone can be freely changed. For example, the switches 346 and 347 are set to high concentration, and the switch 34
When 8 is set to zero, a portion where Y and M have a high density and C has a low density, that is, a "red" portion becomes a dark tone, and this can be set as a "ground color".

In order to read out the data from the image memory 8 for character images and the image memory 21 for halftone images and send them to the laser light modulation circuit 5, these image data are stored in the image memories 8 and 21 and the memory 336 for dark tone. Are stored as dot data, and the same address is assigned to the same pixel. In this embodiment, the image memory address generator 14 controls the addressing of both the image memories 8 and 21 and the dark tone memory 336.
That is, a read address is generated when an image is stored in both the image memories 8 and 21, and a character corresponding to the same pixel, a halftone image, and dot data of a dark tone portion are transmitted.

The dot data of the character image read from the image memory 8 and the dot data of the halftone image read from the image memory 21 act exclusively. That is, when a character is output and printed out, the character portion is a print dot (115 = “1”), and the value for the same pixel read from the ground portion, that is, the dark tone memory is “1” ( That is, when the ground is dark tone), the output of the AND gate 337 becomes "0", and a white character is output. The ground part is “0”
That is, in the case of white or light color, the output of the AND gate 337 becomes "1", and characters are printed.

On the other hand, when printing a halftone image, if the character portion is a print dot, that is, the signal 115 = "1", the output of the AND gate 338 is "0" regardless of the image data 116. There is no image in some places. Therefore, the white color is realized. That is, halftone image data is output when there is no character (115 = “0”). The image output in this manner is as shown in FIG. 17, for example. As can be seen from the figure, a portion having a dark background or a solid black portion can be printed out with white characters, and a portion having a white background can be printed out with black or other single-color characters (described later). Reference numeral 339 is a selector for a character and a halftone image, and when a character image is output, A and C are output by a signal 114 from the control circuit 16, and when A and C output a halftone image, B is output.
And C are controlled to be connected. An OR gate may be used instead of the selector 39. If an OR gate is used, a character image and a halftone image can be output simultaneously, and the number of transfers can be reduced.

In this color image recording apparatus, for example, the first yellow image is read out and a yellow developing device (not shown) is operated to form a yellow image on the photoconductor. Then, the transfer of one color is completed by transferring the yellow image on the photoconductor to the transfer paper wound around the transfer drum. Next, in a similar process, magenta, cyan, and black are sequentially aligned and overlapped to obtain a full-color image of four colors. After that, the selector 339 is switched to obtain a character image in a desired color.

The signal 112 is a signal for controlling the color of the character image as described above, and the data is output from the image memory 8 only when the desired color is printed out. Similarly, when reading a halftone image from the image memory 21, control is performed so that only a desired color image is read,
It is also possible to obtain single or composite color images.

Therefore, as described above, for example, when a character is printed in yellow, the switch 3 in FIG.
If only 46 is set to high density and the other 347 and 348 are set to low density, only the yellow portion of the halftone image is regarded as the background, and the yellow character and the halftone image can be clearly distinguished. That is, even if the yellow portion of the halftone image and the yellow character overlap, the yellow character is expressed as white, so that the character can be clearly recognized.

FIG. 18 is for explaining the fourth embodiment. It should be noted that components having the same functions as those in FIG. 3 are designated by the same reference numerals and the description thereof will be omitted. Therefore, here, the part different from the circuit of FIG. 3 will be mainly described.

In FIG. 18, reference numeral 55 is a blank code generation circuit for whitening out the periphery of the character to be output. When outputting a white-toned halftone image, the blank code generation circuit 55 sends a blank code to the character generator 9 via the selector 56, and a blank is written at a position in the image memory 8 where a character should be printed. . At the same time,
That is, the OR gate 5 is located outside the area where the blank is written.
19, "1" is written by the input 215 of FIG.
An image with a white outline as shown in (a) is written in the image memory 8. On the other hand, the halftone image output data selector 57 connects the input of the AND gate 67 and the output of the halftone image memory 21. Therefore, as shown in FIG. 19B, the final image output from the AND gate 67 is a halftone image in which only the white portion WH in FIG. 19A is removed or a solid image. Next time the character is output, the selector 56 operates so that the character code buffer 10 is connected to the character generator 9. Therefore, in the character generator, the character code is converted into dot data, and the dot data of the character image to be written is written in the character image memory 8. At this time, since the input 215 of the OR gate 54 is "0", only the dot data of the character is written in the character image memory 8. Further, the selector 57 is connected so that the input of the AND gate 67 becomes "1". Therefore, only the character dot data read from the character image memory 8 passes through the AND gate 67, and as the final image, as shown in FIG.
As shown in FIG. 19C, a predetermined character is written in the white space in FIG. 19B.

By the way, the blank code generating circuit 55 carries out the following operation when forming an image as shown in FIG.

First, character codes are sequentially input from the character code buffer 10 (a signal line for inputting the character code is not shown), a blank code is generated for a portion other than the blank code, and a blank code is generated for other portions. Is to send a signal (not shown) to the control circuit 16 to write "1" in the image memory 8 by the input 215. When a signal is input from the blank code generation circuit, the control circuit 16 controls the address generator 14 to generate "1".

In this way, the image memory 8 is stored in FIG.
An image as shown in FIG. In this embodiment, it is assumed that the character code buffer does not include the control code, but all the character codes are stored.

The image based on the data in the memories 8 and 21 shown in FIG. 3 is once displayed on the CRT display.
However, the position and color of the composite character can be confirmed, and after confirmation, printing can be started.

In this color image recording apparatus, a yellow image, a magenta image, a cyan image, a black image, and a character image are sequentially formed on the photoconductor 1, and the respective images are aligned and superposed on the transfer paper. You are getting a full color image.

The color of the character image can be easily selected by selecting a developing device when the character image is printed out (developed).

The blank code generation circuit outputs various codes having different blank sizes to the character generator, and the character generator outputs a blank pattern corresponding to the blank size, so that white portions having different sizes are generated. Can be made.

Although the character patterns are stored in the image memory in this embodiment, other line drawing patterns may be stored. Further, in the present embodiment, the laser beam printer was described as an example of the output device, but the present invention is not limited to this, and can be used in, for example, an inkjet printer, a thermal printer, or the like.

Further, instead of the output device, a disc may be used for filing the synthesized image.

Further, in the present embodiment, the character data and the position designation signal are sent from the external device, but it is also possible to input them by the data input keys provided on the color image recording apparatus side.

The R, G, and B color image data are CCDs.
It can also be sent from a scanner or the like.

Further, a combined image memory (for example, Y, M,
C, Bk).

As described above, according to this embodiment,
The character image and the halftone image can be combined without impairing the sharpness of the character image, and the designated areas can be moved separately for each of the character image and the halftone image. It is possible to efficiently rearrange and synthesize.

Further, according to the present embodiment, for example, a character image or the like can be input by using a code, so that it is possible to connect with other equipment and a versatile image device can be obtained.

Further, according to the present embodiment, the character image can have any color in accordance with the background halftone image, and the reproducibility of the character image and the halftone image can be improved.

Further, according to the present embodiment, it is possible to receive the compressed code from, for example, a facsimile machine by simply adding the input data identification command. Therefore, it is possible to combine various images input from various devices.

Furthermore, according to this embodiment, at least one of the halftone image and the line image can be colored arbitrarily, which is suitable for office work after printing (for example, changing the character color for each data). It is possible to obtain various reproduced images.

Further, according to the present embodiment, the line drawing of a character or the like can be clearly reproduced regardless of the color of the line drawing of the character or the like, the color tone of the image, and the density. The inconvenience of disappearing can be eliminated.

[0065]

According to the present invention, in the color printing information sent from the host computer to the printer side, the printing information corresponding to the image forming order of the printer and the color code irrelevant to the image forming order of the printer are provided. It is possible to obtain an image forming method for a color printer, which is capable of performing printing without trouble even when mixed with the attached print information, and which is superior in operability to the conventional one.

[Brief description of the drawings]

FIG. 1 is a diagram showing an example of a composite type copying apparatus.

FIG. 2 is a diagram showing a state in which characters are superimposed on an image having many black portions.

FIG. 3 is a circuit diagram of a color image recording apparatus showing the entire embodiment of the present invention.

FIG. 4 is a diagram showing an example of character image data.

FIG. 5 is a diagram showing an example of color image data.

FIG. 6 is a diagram showing an example of a character screen stored in a character code buffer.

FIG. 7 is a diagram showing a state of a character input to a character generator and a state of a character after dot conversion.

FIG. 8 is a diagram showing an example in which designated areas of a character image and a halftone image are individually moved, and these two screens are combined.

FIG. 9 is a detailed view of the control circuit 16.

FIG. 10 is a diagram for explaining various commands.

FIG. 11 is a diagram showing a data input unit.

FIG. 12 is a flowchart of a program stored in a ROM 41.

FIG. 13 is a diagram showing a second embodiment in which compressed code data can be input.

FIG. 14 is a diagram showing an example in which a character image, a color halftone image, and a facsimile image are combined.

FIG. 15 is a diagram showing a color image recording apparatus according to a third embodiment of the present invention.

FIG. 16 is a specific configuration diagram of a dark tone extraction circuit.

FIG. 17 is a diagram showing an image state obtained according to the present embodiment.

FIG. 18 is a diagram illustrating a color image recording apparatus according to a fourth embodiment of the present invention.

FIG. 19 is a view for explaining an image state in which a white frame is removed.

[Explanation of symbols]

 7 OR gate 8 and 21 image memory 9 character generator 10 character code buffer 16 control circuit 24 dither processing circuit 28-1 to 28-3 image buffer memory 40 CPU 46,250 data selector 251 buffer memory 252 MH decoder circuit 253 FAX image memory

Claims (2)

[Claims] 1. Image forming data sent from a host computer to a printer through a single channel is formed into a single color or a superimposed image in accordance with a predetermined image forming order using a plurality of types of color forming materials. In the image forming method of a color printer, the image forming data sent from the host computer to the printer side and subjected to the separation processing is provided with image forming data corresponding to the image forming order and a color code irrelevant to the image forming order. When image formation data is given, image formation is performed in accordance with each image formation order for data corresponding to the image formation order, and for image formation data with a color code, the color is formed. Image formation of a color printer, characterized in that the code is converted into color components corresponding to the respective image formation orders to execute the image formation. Law. 2. The image forming method according to claim 1, wherein the image forming data corresponding to the image forming order is image forming data of four colors of Y, M, C and Bk.