JP2004229129A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To attain the acceleration of a processing speed for an image forming apparatus having a function for collecting manuscripts mixed with black-and-white manuscripts and color manuscripts into a sheet of recording paper and then copying. <P>SOLUTION: The apparatus comprises an image input means for reading image data of a manuscript, a color processing means for generating color data from the image data, a black-and-white processing means for generating black-and-white data from the image data, a manuscript determining means for determining a manuscript type of the manuscript based on the image data, a storage control means for storing either of the color data or the black-and-white data according to the determination result by the manuscript determining means, a manuscript collecting means for collecting data corresponding to the manuscript stored by the storage control means into one sheet of recording paper, and a data unifying means for unifying the collected data by the manuscript collecting means into either color data or black-and-white data according to the presence or absence of a color manuscript in the determination by the manuscript determining means. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention reads out image data of a document and performs predetermined processing on the read image data depending on whether the document is a black-and-white document or a color document, thereby outputting output data. The present invention relates to an image forming apparatus that forms an image on a single sheet of recording paper after generating the generated output data and aggregating the generated output data for each predetermined number. The present invention relates to an image forming apparatus capable of improving the use efficiency of a memory by selecting a process, and consequently realizing a high processing speed.
[0002]
[Prior art]
2. Description of the Related Art In a conventional color copying machine (an example of an image forming apparatus), image data is read from a document, and a predetermined process is performed on the image data according to whether the read document is a monochrome document or a color document. Output data is generated by performing the processing, and the generated output data is aggregated by a predetermined number, and then, when an image is formed on one sheet of recording paper (so-called aggregated copy), the following processing is performed.
First, when a predetermined operation device such as a copy start button is operated, originals placed on an automatic original feeder (so-called ADF) are sequentially transported onto an original platen, and the originals are scanned. The read image data is sequentially stored in the memory.
When reading of all the originals is completed, the image data is read from the memory, and it is determined based on the image data whether the read original includes a color original. Such a series of processes is a process called a so-called pre-scan.
When the pre-scan is completed, the image data of the document is read out again from the memory, and the image data is subjected to a predetermined process in accordance with the result of the pre-scan determination (that is, the presence or absence of a color document). (Ie, color processing is selected to generate color data when a color original is included, and black and white processing is selected to generate black and white data when a color original is not included) , Predetermined output data is generated, and the output data is stored again in the memory.
Finally, when the processing for all the image data for each document type is completed, the output data is sequentially read from the memory at a predetermined timing, and a copy image is formed based on the output data (for example, Patent Document 1).
As described above, in a copier having a conventionally known configuration, the presence or absence of a color original is determined by once prescanning all the originals sequentially conveyed on an original platen glass, and output data is determined according to the determination result. By generating an image based on the generated output data on a recording sheet, it is possible to realize an integrated copy according to the type of the original (that is, whether or not there is a color original).
[0003]
[Patent Document 1]
Japanese Patent No. 3015045
[0004]
[Problems to be solved by the invention]
However, the conventional color copier has the following problems.
First, first, in the configuration for performing the prescan, the image data of all the originals to be copied are stored in the memory. Since image data must be read once, a large memory is required and reading takes time.
Second, when the prescan (that is, determination of the presence or absence of a color document) is completed, all the image data is read out again from the memory, and a predetermined value corresponding to the result (the presence or absence of a color document) is read out. (Either color processing or black-and-white processing) to generate output data and then store the output data in the memory again.
As described above, in the color copier having the conventional configuration, the process of reading / writing the image data becomes complicated because the process of reading all the image data twice is required (that is, the use efficiency of the memory is low). This causes a reduction in processing speed, which is a practical problem.
SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to perform predetermined processing on image data read from an original in accordance with the original type (color original or monochrome original). To simplify processing related to reading / writing of image data in an image forming apparatus having a so-called aggregate copy function of forming an image after a predetermined number of output data generated by performing the process are aggregated on one sheet of recording paper. Accordingly, it is an object of the present invention to provide an image forming apparatus capable of improving the use efficiency of a memory, and consequently realizing a high processing speed.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides an integrated information input unit for inputting integrated information regarding an aggregation process,
Image input means for reading image data of the original,
Color processing means for performing color processing on the image data read by the image input means to generate color data;
Black-and-white processing means for performing black-and-white processing on the image data read by the image input means to generate black-and-white data;
For the image data read by the image input means, whether the color original is included in a set of originals to be integrated based on the integrated information input by the integrated information input means is integrated. A document determining means for determining each set of image data;
Storage control means for storing either the color data generated by the color processing means or the black and white data generated by the black and white processing means in a predetermined storage means in accordance with a result of the determination by the document determination means;
A document aggregating means for aggregating a predetermined number of data corresponding to the set of documents to be integrated stored in the predetermined storage means by the storage control means on a single sheet of recording paper;
With
The image forming apparatus is characterized in that reading of the next image by the image input means is started after the document collection of the set of image data to be collected by the document collection means is completed. Is done.
[0006]
Here, as an example of the storage control unit, the original image data read by the image input unit is stored together with the black and white data generated by the black and white processing unit. In the case where black and white originals are mixed, for the area which is the black and white image, the original image data stored corresponding to the area is returned to the color processing means, and the color data generated by the color processing means is stored. Something to do is conceivable.
[0007]
Further, as another example of the storage unit, the storage unit further includes a white data generation unit that generates white data. May store the black-and-white data generated by the black-and-white processing means and the white data generated by the white data generation unit corresponding to the area.
[0008]
As another example of the storage control means, the storage control means further comprises control switching means for arbitrarily switching between the function described in claim 2 and the function described in claim 3. Is also good.
[0009]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments and examples of the present invention will be described with reference to the accompanying drawings to provide an understanding of the present invention. The following embodiments and examples are mere examples embodying the present invention, and do not limit the technical scope of the present invention.
FIG. 1 is a cross-sectional view of a main part showing a schematic configuration of a copying machine according to an embodiment of the present invention, FIG. 2 is a flowchart showing an example of a flow of processing relating to data storage executed in a control device, and FIG. FIG. 4 is a block diagram illustrating an example of a schematic configuration of the control device. FIG. 4 is a flowchart illustrating an example of a flow of processing related to data storage when a color image and a black-and-white image coexist. FIG. FIG. 6 is a flowchart schematically showing another example of the flow of processing related to data storage executed in the control device, FIG. 7 is a block diagram showing another example of the schematic configuration of the control device, and FIG. FIG. 9 is a flowchart showing another example of the flow of the processing relating to data storage when an image and a black-and-white image are mixed, and FIG. 9 is a diagram schematically showing the processing status of image data in aggregated copying.
[0010]
The configuration of the image forming apparatus according to the embodiment of the present invention will be described with reference to FIG.
FIG. 1 is a sectional view of a main part of an image forming unit of a color copying machine X according to an embodiment of the present invention.
As shown in FIG. 1, the color copying machine X includes a transport belt 1 stretched between a pair of rollers, and a recording paper 2 is transported on the transport belt 1 in a direction indicated by an arrow in FIG. It is configured to: On the conveyor belt 1, a black-and-white (black) image forming area B, a cyan image forming area C, a magenta image forming area M, and a yellow image forming area Y are provided in this order from the right. A photoconductor drum 5 is disposed on each of the photoconductor drums, and a transfer roller 6 is disposed below the transport belt 1 so as to face each of the photoconductor drums. (Note that the arrangement order of the image forming areas B, C, M, and Y is not particularly limited, and this arrangement can be changed as appropriate.)
[0011]
In each image forming area, a main charging device 7, an optical system 8 for image exposure, and a developing device for toner of a color corresponding to each image forming area are arranged in this order around the photosensitive drum 5. ing. That is, the black and white image forming area B is filled with black and white developer 9B filled with black toner, the cyan image forming area C is filled with cyan developer 9C filled with cyan toner, and the magenta image forming area M is filled with magenta toner. The magenta developing device 9M and the yellow image forming area Y are provided with a yellow developing device 9Y filled with yellow toner. Further, a static eliminator (not shown) and a cleaning device 10 are arranged between the area where the transfer roller 6 is provided and the main charger 7.
In addition to the image forming unit shown in FIG. 1, the color copying machine X includes devices (for example, a sheet feeding unit, a sheet conveying unit, or a sheet discharging unit) provided in a general four-tandem type color copying machine. Etc.), but they do not have any particular features, and therefore description thereof is omitted here.
[0012]
Next, an image forming cycle in each image forming area will be described by taking the monochrome image forming area B as an example.
First, the photosensitive drum 5 is uniformly charged to a predetermined polarity by the main charger 7 including a corona charger or a contact charging roller. Next, image exposure is performed by light irradiation from an optical system 8 such as an LED, and an electrostatic latent image is formed on the surface of the photosensitive drum 5. The light irradiation by the optical system 8 is performed according to a control command calculated by the control device 13 based on image data read from a document by the scanner device 12. As a result, an electrostatic latent image is formed on the surface of the photosensitive drum 5 based on the image data of the document placed on the scanner device 12 for copying. The image processing performed on the image data by the control device 13 will be described in detail later.
Then, the electrostatic latent image formed on the surface of the photoconductor drum 5 is developed by transferring the toner by the black-and-white developing device 9B filled with black toner. A toner image is formed by the toner. The charge polarity of the toner image is the same as the charge polarity of the photosensitive drum 5 charged by the main charger 7 when development is performed by so-called reverse development. Has a polarity opposite to the charging polarity of the photosensitive drum 5. The toner image formed by the black toner formed on the surface of the photosensitive drum 5 in this manner is transferred onto the recording paper 2 conveyed on the conveying belt 1 in an area (transfer area) facing the transfer roller 6. Transcribed. This transfer is performed by applying a bias voltage having a polarity opposite to that of the toner image to the transfer roller 6. Instead of using the transfer roller 6, a corona charger may be used to transfer the image by charging the back surface of the recording paper 2 to a polarity opposite to that of the toner image.
After the above-described transfer process is completed, static elimination of the photosensitive drum 5 and cleaning of toner remaining on the surface of the photosensitive drum 5 are performed by a static eliminator and the cleaning device 10 (not shown). A cycle takes place.
[0013]
As described above, in the black and white image forming area B, a black and white image made of black toner is formed on the recording paper 2.
Through the same steps, on the recording paper 2, the cyan image formed of cyan toner in the cyan image forming area C, the magenta image formed of magenta toner in the magenta image forming area M, and the yellow image formed area Y Thus, a yellow image composed of yellow toner is formed.
That is, when a monochrome image is formed, the above-described image forming cycle is executed only in the monochrome image forming area B, and a monochrome image is formed on the recording paper 2.
When a color image is formed, the above-described image forming cycle is executed in each of the image forming areas B, C, M, and Y, and the single-color toner images of the respective colors are superimposed on the recording paper 2 to form a color image. An image is formed.
The recording paper 2 on which the image has been formed in this way is discharged from the transport belt 1 and introduced into the fixing device 11, where the image (toner) is fixed, and then discharged onto a predetermined tray.
[0014]
In the color copying machine X, developing rollers 9Br, 9Cr, 9Mr, and 9Yr are provided in the developing units 9B, 9C, 9M, and 9Y so as to face the photosensitive drum 5, respectively. By the driving rotation of the developing roller, the toner filled in each of the developing devices is transported by the developing rollers to a portion facing the photosensitive drum 5, and the toner is used to transfer the toner to the surface of the photosensitive drum 5. Is developed.
Of the developing units 9B, 9C, 9M and 9Y, the developing unit 9B for black toner is a so-called two-component developing system, while the developing units 9C, 9M and 9M for the remaining colors (chromatic colors) are used. 9Y is a so-called non-magnetic one-component developing system.
Therefore, in the color developing units 9C, 9M, and 9Y of the non-magnetic one-component developing system, only the insulating toner is used as the developer, whereas in the monochrome developing unit 9B of the two-component developing system, the toner (basically, (A magnetic material) and a magnetic carrier for imparting charge to the toner.
[0015]
Further, in the color copying machine X, since the photosensitive drums 5 arranged in each image forming area are juxtaposed in the conveying direction of the transfer belt 1, a full-color image and black and white, cyan, magenta, and yellow colors are provided. In any case of forming a single-color image, all four photosensitive drums 5 are set to be driven to rotate.
Here, since the black-and-white developing device 9B is of a two-component developing type, it is set so as to be rotationally driven during rotation of the opposing photosensitive drum 5 regardless of whether or not to perform toner transfer. I have. This is to prevent the magnetic carrier from damaging the surface of the photosensitive drum 5.
On the other hand, each of the color developing units 9C, 9M, and 9Y for cyan, magenta, and yellow is a non-magnetic one-component developing method without a magnetic carrier. The operation is performed in accordance with the body drum 5 (the developing rollers 9Cr, 9Mr, and 9Yr are driven to rotate), but when the toner of each color is not transferred, the operation is performed regardless of whether the photosensitive drum 5 is rotating or not. (The rotation driving of the developing rollers 9Cr, 9Mr, and 9Yr) is controlled to be stopped.
The control of each of the developing rollers 9Br, 9Cr, 9Mr, 9Yr is performed by a control device 13 including a CPU and its peripheral devices.
[0016]
With the above configuration, in the color copying machine X, an image based on image data read from a document placed on a document table of the scanner device 12 is formed on one sheet of recording paper. Is possible. Such an operation mode is called a normal copy function to distinguish it from the integrated copy function described below.
In addition to the normal copying function, the color copying machine X forms a so-called aggregation in which a predetermined number of image data read from an original placed on the original platen is aggregated on one sheet of recording paper. It has a copy function.
As the aggregate copy function, a 2in1 copy in which two originals are combined on one recording sheet to form an image, a 4in1 copy in which four originals are combined, and the like are generally used.
For example, when 4 in 1 copy is selected, the read image data is reduced to 1/4 before being used in the image forming process, and the reduced image data is used as a set of four image data. Thus, one image data is created. In other words, in the 4-in-1 copy, an image based on image data created by combining (pasting) a set of four image data is formed on one sheet of recording paper. Is formed.
Switching of the operation mode (normal copy or aggregated copy) and input of aggregated information such as how many sheets are set as one set are performed by operating a display operation unit (not shown) provided on the front of the apparatus. Further, the control according to the selected and designated operation modes is realized by the control device 13 according to a predetermined program.
It should be noted that since the processing itself capable of realizing such an integrated copy function is well known, the description thereof is omitted here, and the ordinary integrated copy function, that is, the read image data is integrated in the order of reading. We focus on the parts that are different from the case and explain in detail later.
[0017]
Here, when performing an aggregate copy by a color copying machine, originals supplied from an ADF or the like (not shown) include an original including a color image (color original) and an original including only a black and white image (black and white original). Are mixed.
For this reason, in a conventional color copier, when performing an aggregate copy of a predetermined number of originals, the type of the original (whether or not the original includes a color image) is determined by pre-scanning all the originals. However, according to the result of the determination, the combined document is switched between monochrome printing and color printing.
However, in such a configuration, as described above, processing related to reading / writing of image data becomes complicated (that is, the use efficiency of the memory is low), and the processing speed is reduced, which is a practical problem. .
Therefore, in the present embodiment, the document type (color, black and white) is determined while reading image data (that is, black and white data and / or color data) from a sequentially conveyed document, and processing according to the document type is performed. The generated data (color data or black and white data) is stored in a predetermined storage means (memory 106 to be described later) in a state where a predetermined number of the data are collected on one sheet of recording paper, and unified into black and white or color as described above. By collecting and printing the set of originals on a single sheet of paper, it is possible to save memory and shorten the reading time.
According to such a configuration, it is possible to unify the storage data stored in the predetermined storage means in a consolidated state into either color data or black and white data without performing prescan as in the conventional configuration. Therefore, the efficiency of memory use can be improved by greatly simplifying the processing for reading / writing image data, and the processing speed can be increased.
Hereinafter, a memory control method according to the document type (the presence / absence of a document including a color image) executed when performing the aggregate copy by the color copying machine X according to the present embodiment will be described.
[0018]
The image processing executed by the control device 13 in the color copying machine X according to the embodiment of the present invention will be described in detail with reference to FIGS.
Here, FIG. 2 is a flowchart showing a flow of image processing executed by the control device 13, and FIG. 3 is a block diagram schematically showing a schematic configuration of the control device 13. Hereinafter, S1, S2,... Correspond to the reference numerals shown in FIG. 2 and are the numbers of the processing procedures (steps).
(S0)
First, when the aggregation mode is set, the operator inputs "aggregation information such as how many pages of images are aggregated per sheet" using the display operation unit. The consolidated information is stored in a storage unit (not shown).
(S1)
Next, when the originals are sequentially read, the original reflected light (image data) from the original read by the scanner device 12 as RGB (R: red, G: green, B: blue) analog signals is output. After being converted into digital data by the A / D conversion unit, the digital data is input to the control device 13.
(S2)
The image data input to the control device 13 is first subjected to shading correction. The shading correction is a process for removing various distortions that occur in the illumination system (for example, the exposure distribution characteristics of an exposure lamp) and the imaging system (for example, the sensitivity distribution characteristics of a CCD) in the scanner device 12.
(S3)
Next, predetermined input processing is performed on the image data subjected to the shading correction. This input processing includes MFT correction or chromatic aberration correction for RGB reflectance signals in image data.
(S4)
Thereafter, the image data that has been subjected to the predetermined input processing is subjected to a scanner color correction processing for correcting a reading variation in an image pickup system (CCD) of the scanner device 12.
(S5)
Then, the image data that has passed through the step S4 is branched, and one of them is input to the color / monochrome determination unit 101, and is used to determine whether the image data is a monochrome image or a color image. This determination is performed for each set of images to be combined (for example, one set of four sheets in the case of 4-in-1 combination), which is determined based on the aggregation condition input in advance as described above. That is, for example, if even one copy of a color image is included anywhere in a set of four images, it is determined at that time that the set of images is a color image. If no color portion is included anywhere in the set of four sheets, it is determined that the set of image groups is a monochrome image.
The determination of the document type (image type) in the color / monochrome determination unit 101 can be performed based on the balance of the RGB signals in the input image data. Since such determination processing is a known technique, a detailed description is omitted here.
The determination result of step S5 is input to a selector 105 described later, and is used in a determination process (step S8) for switching the image processing to be uniformly performed on the input set of image data to be integrated. .
(S6), (S7)
Further, the other of the image data branched in step S4 is subjected to digital processing according to the scaling set by the user, and is scaled to a predetermined magnification. 105 is input.
(S8)
Then, in the selector 105, one set of input image data is determined according to the document type of the one document group determined in step S5 (that is, the determination result by the color / monochrome determination unit 101). The image processing unit that outputs the data group is selected (switched). That is, the input image data group is input to either the color processing unit 102 or the black-and-white processing unit 103 in accordance with the type of the document, and is uniformly subjected to predetermined image processing.
More specifically, if a color image portion comes at the beginning of one set of combined originals, it is determined that the original is a color original from the beginning, and the entire set of originals is sent to the color processing unit 102 without any problem. If it is determined that the image is an image from the end of one set of the group of original documents, the grouping processing unit described later unifies the color processing of one group of the group of original documents.
The color / black-and-white determination unit 101 determines that the data is black-and-white data when a portion that is determined to be black-and-white comes first, and the data is transferred to the black-and-white processing unit 103. If it is determined that the set of combined originals is a black-and-white image to the end, the combining processing unit described later unifies the set of combined originals and performs black-and-white processing. If the original is changed to a color original in the middle (that is, a part of the original is color), the selector 105 sends the image to the color processing unit 102 from that part according to the determination of the color / monochrome determination unit 101. To start color image processing. As a result, in the memory 106, a black and white image by the black and white processing unit 103 before the color image is found and a color image by the color processing unit 102 after the color image is found are mixed. If a part by the color processing unit 102 and a part by the black-and-white processing unit 103 coexist in the combined original, the appearance becomes unsightly and the image quality deteriorates. Therefore, color processing is performed by looping back the monochrome image to the color processing unit 102, as described later in the aggregation processing of S21. See below for details.
The color processing unit 102 performs a predetermined process to be performed on a color image, and specifically, performs processes from S9 to S15 in FIG.
On the other hand, the black-and-white processing unit 103 performs a predetermined process to be performed on a black-and-white document, and specifically performs the processes from S16 to S20 in FIG.
[0019]
Here, the processing in the color processing unit 102 will be described first.
(S9)
The color processing unit 102 first converts the RGB image data according to the R, G, and B light intensities of the input image data into C (cyan), Y (yellow), and M (magenta) densities. A color space conversion process (shown by a correction inversion process in FIG. 2) for converting into a corresponding CMY format signal (density recording signal) is performed, and the original RGB format image data is converted into CMY format image data by a known method. Is converted by
(S10)
Subsequently, in the color processing unit 102, a black generation process for generating a black (K) signal from the three CMY color signals converted in step S9, and further, a K generation process for generating black from the original CMY signal. A process of subtracting the signal to generate a new CMY signal (indicated by an adaptive UCR in FIG. 2) is performed, and the CMY format image data is converted into CMYK format image data by a known method.
(S11)
The image data converted into the CMYK format in step S10 is subjected to printer color correction, and output characteristics relating to image formation, such as a deviation of a toner color from a theoretical color and development characteristics, are corrected by a known method. You.
(S12)
Next, the image data that has been color-corrected in step 11 is subjected to exposure γ correction, and the brightness is adjusted so that the image data is printed at a predetermined (user-desired) brightness. Adjustment methods are well known.
(S13)
Further, the gamma-corrected image data in step S12 is subjected to a gradation table process.
For example, in an electrophotographic process, it is difficult to obtain output characteristics that change linearly with image data due to the charging characteristics of the photosensitive drum 5 and toner. Therefore, by correcting the output characteristics of the printer engine in step S13, a high-quality copy image can be obtained.
(S14)
Further, the image data subjected to the gradation table processing in step S13 is subjected to a screen processing.
(S15)
Finally, the image data subjected to the screen processing in step S14 is subjected to size processing according to the paper size of the recording paper on which the image is to be formed, and the CMYK format color data suitable for color printing (in FIG. 3, surrounded by a virtual line D1). (Indicated by a signal line CMYK).
[0020]
Next, processing in the one black-and-white processing unit 103 will be described.
(S16)
First, the black-and-white processing unit 105 uses black and white data for outputting black by using the density of G among the RGB digital data in the input image data. (Indicated by the enclosed arrow K) is generated.
Here, the intention of using the density of G in the generation of the black and white data is that the green signal is the signal having the highest visibility of human eyes (the light and shade in the image data is captured most).
Here, in this embodiment, the original RGB digital data (scanner data) read by the scanner device 12 is added to the black and white data at this point in addition to the signal (K) for outputting black. (In FIG. 3, it is indicated by signal lines RGB surrounded by a virtual line D2 ').
This is because, as described above and as will be described in detail later, when the originals to be combined this time include not only black and white originals but also color originals, the combined originals use only the black and white developing unit 9B. The original scanner data is looped back to the color processing unit 102 because it is necessary to perform color printing by using a combination of the black and white developing unit 9B and / or the color developing units 9C, 9M, and 9Y instead of black and white printing. This is because the process of converting the monochrome data into the color data is performed (that is, the process indicated by the arrow A in FIG. 2).
It should be noted that the original RGB scanner data is unnecessary and is discarded when it is determined that the original document thus aggregated is only a black and white original document.
The processing from step S17 to S20 following step S16 is the same as that in the case of the color processing described above, and a description thereof will not be repeated.
Through such a series of processes, the image data input to the black-and-white processing unit 103 is converted into black-and-white data suitable for black-and-white printing (in FIG. 3, indicated by a signal line K surrounded by a virtual line D2). On the other hand, the original scanner data (indicated by signal lines RGB surrounded by a virtual line D2 'in FIG. 3) is input to the memory 106 in a state where it is provided.
[0021]
(S21)
As described above, in the color copying machine X according to the present embodiment, the switching between the image processing for color printing and the image processing for black-and-white printing is performed simultaneously with the reading of the image data for one set of input aggregated image data. The image data that has been subjected to the respective image processing is input to the memory 106.
Then, the input image data is aggregated in step S21.
As described above, the aggregation processing includes processing for reducing image data to a predetermined magnification (for example, 1/4 for 4 in 1) in accordance with setting of aggregation information (for example, 4 in 1 copy or the like) by a user, The process includes a process of aggregating the reduced image data for each predetermined number of images (for example, four images in the case of 4-in-1) to create one image data.
(S22)
Then, is there a document determined to be a color document by the color / monochrome determination unit 101 in the image data consolidated in step S21 (that is, a color document and a monochrome document are mixed in the consolidated image data). The image data stored in the memory 106 is unified into either color data or black and white data (details of which will be described later).
(S23)
Finally, the output data stored in the memory 106 in a state where the data is unified into any of the data in the step S22 is read out at a predetermined timing and sequentially input to the optical system 8. As described above, an electrostatic latent image based on the output data (that is, image data of the document) is formed on the surface of the photosensitive drum 5, and a copy image is formed on the recording paper in a state of being aggregated for each predetermined number of sheets. You.
[0022]
Here, if the original is composed of only a color original or only a black and white original, it is stored in the memory 106 when the input signals from the color processing unit 102 or the black and white processing unit 103 are aggregated. Since the data is unified into either color data or black and white data, an image can be formed by sequentially reading the data from the memory 106.
However, when the originals to be aggregated and copied are a mixture of a color original and a black and white original, the input signals from the color processing unit 102 and the monochrome processing unit 103 are simply aggregated as they are, Since non-uniform data in which black-and-white data and color data are mixed is stored, it may be inconvenient that an image with poor appearance is obtained in the image forming process.
Therefore, in the present embodiment, when the original includes both black and white originals (black and white data) and color originals (color data) in step S22, the black and white data stored in the memory 106 (that is, The original scanner data is looped back to the color processing unit 102, and a process of generating color data by performing color processing on the original scanner data is executed (in FIG. 2, the flow of the process is indicated by an arrow A). In FIG. 3, a signal line RGB surrounded by a virtual line D2 ″ is shown), and a process of unifying data stored in the memory 106 into color data is performed.
When the memory control ends, the process returns to S1, and reading of the next set of combined originals is started. Actually, since the processing in S2 to S22 is performed in a short time, the reading of the image data in S1 is performed without interruption. In order to read the image even faster, the document may be supplied to the reading unit during the processing of S2 to S22. Further, a buffer may be provided to read the document in advance. Is also possible.
By performing such processing, in the present embodiment, when performing an aggregate copy of an original in which a black-and-white original and a color original are mixed, the black-and-white original is once recognized as a black-and-white original, and the black-and-white data is converted. Although the output data is finally stored as output data in the memory 106, the output data is all stored in a unified state in the CMYK format color data. Can be.
As described above, the feature of the image processing method according to the present embodiment is that the document type is determined while reading the image data from the document, the output data corresponding to the document type is stored in the memory 106, and the stored data is stored. In consolidating the collected data, memory control is performed to make unified data (either black and white data or color data) according to the presence or absence of a color original for the entire set of originals to be aggregated, and such unification. Since the conversion is performed for each set of the group of originals, the data can be unified only by reading the original once.
Due to this characteristic point, according to the present embodiment, when the image data subjected to the predetermined processing is aggregated and stored in the memory 106 as force color data, prescanning is performed for all the originals, and all the originals are scanned. Compared with the conventional configuration which requires reading / writing of image data many times, it is possible to store the output data in the memory 106 in a state where the format of the output data is unified by extremely simple processing. Significant improvement can be achieved, and the processing time can be shortened.
[0023]
Next, referring to FIG. 4, when performing the processing in step S22, specifically, when performing an aggregated copy of an original in which a black-and-white original and a color original are mixed, the output data is unified into color data and the memory is unified. The flow of the processing stored in the storage 106 will be described in detail. FIG. 4 is a block diagram schematically showing a flow of data (signal) in the control device 13.
First, in the control device 13, RGB digital data (indicated by scanner data in the figure) obtained by the scanner device 12 and subjected to predetermined input processing is converted into the color / monochrome data as described above. The data is input to the determination unit 101 and the selector 105 in parallel.
The color / black and white determining unit 101 that has received the scanner data determines whether the currently processed scanner data is a color image or a black and white image based on the received scanner data. That is, a signal indicating that the image is a color image) is input to the selector 105 and the counter 107.
Upon receiving the determination result from the color / monochrome determination unit 101, the selector 105, based on the determination result, converts the input scanner data into the monochrome processing unit 103 and the color processing unit 102 arranged at the subsequent stage. Is determined.
The black-and-white processing unit 103 or the color processing unit 102 to which the scanner data is input from the selector 105 performs predetermined processing on the scanner data to generate black-and-white data or color data. Is output to the memory 106. Note that the black and white data at this point is provided with scanner data as described above or as shown in FIG.
On the other hand, in the counter 107 to which the determination result of the selector 101 is input, the determination result is sequentially stored, so that, of the scanner data input from the scanner device 12, the sub-scanning direction Has the function of storing the position information (memory address) and outputting the information (that is, the information specifying the position of the area that is a color image in the scanner data) to the counter determination unit 108 described later.
[0024]
In the memory 106 that receives data (black and white data and color data) from the color processing unit 102 and the black and white processing unit 103, the data is sequentially stored in the sub-scanning direction.
Further, in the memory 106, the data stored in the memory 106 is reduced to a predetermined magnification in accordance with the setting (the number of sheets to be combined) selected by the user, and the data is stored in a printable area on one sheet of recording paper. A pasting process (shown in FIG. 2 as S21: aggregation process) is performed.
Here, if the original to be copied this time is only a color original or only a black-and-white original, the stored data stored in the memory 106 at this time is data unified into either color data or black-and-white data. In the case of an original copy in which a color original and a black and white original are mixed, color data and black and white data are mixed in the stored data at this time. A process of changing to the color data and unifying the entire stored data to the color data is performed.
Specifically, first, the stored data is temporarily read from the memory 106 in which the stored data is stored, and is input to the counter determination unit 108.
Here, as described above, the counter judging unit 108 receives, from the counter 107, information for specifying the position in the sub-scanning direction of the color image area in the scanner data read by the scanner device 12 this time. Has been entered.
Therefore, the counter determination unit 108 immediately determines the area of the stored data, which is a color image (color data) and the area of a black and white image (black and white data), based on the information input from the counter 107. Can be identified.
Therefore, of the storage data input to the counter determination unit 108, data in an area that is color data (counter ON: indicated by color data in the figure) is stored again in the memory 106 as it is. For an area that is black and white data (counter OFF: indicated by black and white data in the figure), the scanner data added to the black and white data is looped back to the color processing unit 102 and converted to color data. , Stored in the memory 106.
According to the present embodiment, when a series of mixed color and black-and-white originals is combined and copied, the above-described series of processing is executed by the control device 13 and finally stored in the memory 106. The data can be all data unified into CMYK format image data (color data). By sequentially inputting the data to the optical system 8, a high-quality color image without discomfort is obtained. Can be imaged.
[0025]
Next, the state of the image data in the memory 106 in the control device 13 when the aggregated copy is performed based on the control method described above will be described in detail with reference to FIG. 5 which is a state transition diagram.
FIG. 5 schematically shows a processing state of the image data when the 4-in-1 copy is selected in the color copying machine X.
(S100)
First, step S100 shows the state after steps S1 to S21 in FIG. 2 have been executed. The image data read from the document is collected in that order (page order) and stored in the memory 106. Is stored in the memory.
For this reason, at this time, CMYK format color data read from a color document and black and white data read from a black and white document are mixed.
As shown in FIG. 5 and FIG. 5, the scanner data (original RGB digital data) of the document is added to the monochrome data.
(S101)
Then, in step S101, a process (corresponding to an arrow A in FIG. 2) of looping back the black-and-white data (that is, scanner data) stored in the memory 106 to the color processing unit 102 is executed. The RGB data added to the data is converted into CMYK format color data, and all the image data collected on one sheet of recording paper are unified into color data.
(S102)
Finally, in step S102, after the image data unified into the color data in step S101 is reduced according to the type of the selected aggregate copy (currently 4in1 copy) (this time is reduced by 1/4) , Are arranged (attached) to a predetermined printable area Z and collected as one image data.
Incidentally, the one aggregated image data is sequentially read out from the memory 106 and input to the optical system 8 to form an electrostatic latent image corresponding to the image data on the surface of the photosensitive drum 5. Are formed in the same manner as in the normal copying described above.
As described above, in the color copying machine X, when the above-described series of processes (programs) are executed in the control device 13, when an original in which a color original and a black-and-white original are mixed is collectively copied, It is understood that the copied image is formed in a state where the image data generated from the document to be combined is unified into the color data.
[0026]
【Example】
(Example 1)
In the above-described embodiment, when the combined originals include a black-and-white original and a color original, the black-and-white data generated by the black-and-white processing (actually, the scanner data added to the black-and-white data) is converted into the original. By looping back to the color processing unit 102 and regenerating color data, the data stored in the memory 106 is finally unified into color data in CMYK format.
By the way, among color originals mixed with black-and-white originals, there are many originals in which a color photograph is attached to a part of a text original, or a color original such as a company logo is included only in the header or footer of the text original. Can be seen.
When copying such a color original, it is not necessary to print all the areas in color as in the above-described embodiment. Rather, the area of the text original is printed in black and white, and only the photograph, the header portion or the footer portion is printed. Is desirable.
According to such an embodiment, the present embodiment is superior to the above-described embodiment in terms of image quality in the black and white area, processing speed, and saving of color toner.
Therefore, in the present embodiment, a mode suitable for printing a document as described above by executing the following image processing in the control device 13 is considered. Note that the difference between the present embodiment and the above-described embodiment is a process for unifying the black and white data generated by the black and white process as color data, specifically, the step S22. The description focuses on the parts.
[0027]
FIG. 6 is a flowchart showing the flow of image processing executed by the control device 13 in the color copying machine X according to the present embodiment, and FIG. This will be described in detail with reference to FIG. 7, which is a block diagram schematically showing the schematic configuration.
As is clear from FIG. 6, the flow of the processing is substantially the same as that of the above-described embodiment (see FIG. 2), but only the processing in step S22 is different.
The process in step S22, that is, the process of converting (unifying) the monochrome data generated by the monochrome process into the CMYK format color data will be described with reference to FIG.
In the embodiment described above, in step S22, the monochrome data stored in the memory 106 (actually, the scanner data added to the monochrome data) is read out, and the CMYK data is looped back to the color processing unit 102. By performing processing to regenerate the color data in the format (see signal lines RGB surrounded by virtual lines D "in FIG. 3), the stored data for the aggregated original is unified into color data in the CMYK format. .
However, in the present embodiment, in step S22, white data (shown by a signal line K surrounded by a virtual line D2 in FIG. 7) inputted from the CMY white Is merged with a signal line CMYK surrounded by a virtual line D2 '''to generate color data in CMYK format (shown in FIG. 7 by a signal line CMYK surrounded by a virtual line D3). Constitute.
With such a configuration, the data stored in the memory 106 is unified into color data in CMYK format, and at the same time, the area of the text document is printed by monochrome printing (that is, printing using only black toner). Therefore, it is possible to improve the image quality and prevent waste of the color toner.
Further, as in the above-described embodiment, the process of looping back the black and white data (scanner data) stored in the memory 106 can be omitted, which is advantageous in terms of processing speed.
[0028]
Next, referring to FIG. 8, the processing in the step S22, specifically, when an original in which a black-and-white original and a color original are mixed is to be collectively copied, all image data are unified into CMYK format color data. The flow of processing stored in the memory 106 will now be described in detail. FIG. 8 is a block diagram schematically showing a flow of data (signal) in the control device 13.
This figure is also substantially the same as the above-described embodiment (see FIG. 4), and therefore only the different parts will be described.
In the present embodiment, the stored data (color data and black and white data) is stored in the memory 106, and a part of the stored data (that is, black and white data) is looped back. At the time when the data is stored in the CMYK color data. In other words, the processing for changing (unifying) the stored data (that is, color data and monochrome data) input from the monochrome processing unit 103 and the color processing unit 102 to color data is different.
More specifically, as shown in the figure, in the present embodiment, of the stored data, an area that is color data (indicated by a counter ON in the figure) is stored in the memory 106 as it is, and An area that is data (indicated by a counter OFF in the figure) is merged with the white data (C, M, Y) from the CMY white data generation unit 104 and converted into CMYK format color data. By storing the data in the memory 106, the stored data is unified into color data.
By executing the above processing in the control device 13, according to the present embodiment, even in the case where the original in which the color original and the black-and-white original are mixed is to be collectively copied, the original is finally stored in the memory 106. The data can be all data unified into CMYK format image data (color data), and a color image can be formed by sequentially inputting the data to the optical system 8.
Further, in this embodiment, since the black-and-white image area is printed only with black toner, the image quality of black-and-white printing is improved as compared with the above-described embodiment, and wasteful toner (color toner) is wasted. Can be prevented.
Furthermore, according to the present embodiment, the process of looping back the data for the black-and-white image area is omitted, which is advantageous in terms of processing speed as compared with the above embodiment.
[0029]
Next, the state of the image data in the memory 106 in the control device 13 when the aggregated copy is performed based on the control method described above will be described in detail with reference to FIG.
FIG. 9 schematically shows a processing state of the image data when the 4-in-1 copy is selected in the color copying machine X.
(S200)
First, step S200 shows the state after steps S1 to S21 in FIG. 6 have been executed, and the image data read from the document is collected in that order (page order) and stored in the memory 106. Is stored in the memory.
For this reason, at this time, CMYK format color data read from a color document and black and white data read from a black and white document are mixed.
(S201)
Then, in step S201, a process of merging CMY white data with the black and white data stored in the memory 106 (corresponding to the signal line CMY surrounded by the virtual line D2 ′ ″ in FIG. 3) is executed. , The monochrome data is converted into color data in CMYK format, and all image data aggregated on one sheet of recording paper are unified into color data.
(S202)
Finally, in step S202, after the image data unified into the color data in step S201 is reduced according to the type of the selected aggregated copy (currently 4in1 copy) (this time is reduced by 1/4) , Are arranged (attached) to a predetermined printable area Z and collected as one image data.
Incidentally, the one aggregated image data is sequentially read out from the memory 106 and input to the optical system 8 to form an electrostatic latent image corresponding to the image data on the surface of the photosensitive drum 5. Are formed in the same manner as in the normal copying described above.
As described above, in the color copying machine X, when the above-described series of processes (programs) are executed in the control device 13, when an original in which a color original and a black-and-white original are mixed is collectively copied, It is understood that the copied image is formed in a state where the image data generated from the document to be combined is unified into the color data.
[0030]
(Example 2)
Furthermore, a form in which the control device 13 has a function of arbitrarily switching the processing in the above-described embodiments and examples according to the needs of the user is also conceivable.
By providing such a switching function, the user selects the processing according to the above-described embodiment when giving priority to the image quality of the copied image (that is, color printing), and selects the processing speed and the image quality of the monochrome image. When priority is given to (1), a usage method such as selecting the processing according to the above-described embodiment becomes possible, and it is possible to realize a color copying machine capable of realizing image processing according to the needs of the user.
[0031]
【The invention's effect】
As described above, according to the present invention, the image data is generated by reading the image data of the original placed on the original platen and performing predetermined processing on the read image data in accordance with the type of the original. In an image forming apparatus configured to form an image on recording paper based on output data, since the type of image processing is unified for each set of originals to be combined, it is necessary to read / write image data. Such processing can be simplified, the use efficiency of the memory can be improved, and the processing speed can be increased.
[Brief description of the drawings]
FIG. 1 is an essential part cross-sectional view showing a schematic configuration of a copying machine according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating an example of a flow of processing related to data storage executed in the control device.
FIG. 3 is a block diagram illustrating an example of a schematic configuration of a control device.
FIG. 4 is a flowchart illustrating an example of a flow of processing relating to data storage when a color image and a monochrome image are mixed.
FIG. 5 is a diagram schematically showing a processing status of image data in an integrated copy.
FIG. 6 is a flowchart showing another example of the flow of processing related to data storage executed in the control device.
FIG. 7 is a block diagram showing another example of the schematic configuration of the control device.
FIG. 8 is a flowchart illustrating another example of the flow of processing relating to data storage when a color image and a monochrome image are mixed.
FIG. 9 is a diagram schematically showing a processing status of image data in an integrated copy.
[Explanation of symbols]
X: Color copier
1 ... conveyor belt
2. Recording paper
5. Photoconductor drum
6… Transfer roller
7… Main charger
8 Optical system
9B: Black and white developing unit
9C: Cyan developing unit
9M: Magenta developing device
9Y: Yellow developing unit
9Br: developing roller
9Cr developing roller
9Mr developing roller
9Yr: developing roller
10. Cleaning device
11 ... fixing device
12 ... Scanner device
13 ... Control device
101: Color / monochrome determination unit
102: Color processing unit
103: Black and white processing unit
104: CMY white data generation unit
105 ... selector
106… Memory
107… Counter
108… Counter judgment unit
S1, S2, ... Number of processing procedure (step)

Claims (4)

An aggregation information input unit for inputting aggregation information regarding the aggregation processing;
Image input means for reading image data of the original,
Color processing means for performing color processing on the image data read by the image input means to generate color data;
Black-and-white processing means for performing black-and-white processing on the image data read by the image input means to generate black-and-white data;
For the image data read by the image input means, whether the color original is included in a set of originals to be integrated based on the integrated information input by the integrated information input means is integrated. A document determining means for determining each set of image data;
Storage control means for storing either the color data generated by the color processing means or the black and white data generated by the black and white processing means in a predetermined storage means in accordance with a result of the determination by the document determination means;
A document aggregating means for aggregating a predetermined number of data corresponding to the set of documents to be integrated stored in the predetermined storage means by the storage control means on a single sheet of recording paper;
With
An image forming apparatus, wherein reading of a next image by the image input means is started after the document collection of the set of image data to be collected by the document collection means is completed. The storage control means includes:
In addition to the black and white data generated by the black and white processing means, the original image data read by the image input means is stored.
If the original contains both color images and black and white originals,
2. The image processing apparatus according to claim 1, wherein, for the area that is the monochrome image, the original image data stored corresponding to the area is returned to the color processing means, and the color data generated by the color processing means is stored. The image forming apparatus as described in the above. The storage control means includes:
And further comprising white data generating means for generating white data,
If the original contains both color images and black and white originals,
2. The area as the monochrome image, wherein the monochrome data generated by the monochrome processing unit and the white data generated by the white data generation unit are stored in correspondence with the area. Image forming apparatus. The image forming apparatus according to claim 1, wherein the storage control unit further includes a control switching unit that arbitrarily switches between the function described in claim 2 and the function described in claim 3.

Images