JP2005026835A - Image processing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology of facilitating setting of a link mode in order to obtain a print image of high quality even in a link print. <P>SOLUTION: An image processing apparatus A is provided with: an image forming apparatus 100 for printing an image represented by image data onto a recording medium; a means 131 of the image forming apparatus for printing a reference image AcP on the recording medium; a communication means ACP for receiving the image data of an original reading apparatus of an image processing apparatus B at a remote place; a means IPP for generating and storing adjustment data for correcting the image data of the original reading apparatus into image data for the image forming apparatus 100 to print out with high image quality on the basis of the image data which the original reading apparatus has obtained by reading the recording medium of the reference image; and an image quality processing means IPP for correcting the image data of the original reading apparatus of the image processing apparatus B and received by the communication means ACP by using the adjustment data and giving the corrected data to the image forming apparatus 100. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image processing apparatus that prints image data received by communication and / or an image processing apparatus that transmits an image read from a document by communication, and more particularly to image data obtained by reading an image by a document reading device of the image processing apparatus. The present invention relates to an image processing apparatus suitable for use in a linked printing system that transfers to one or more image forming apparatuses through communication and prints out the image forming apparatus there. The image processing apparatus of the present invention can be used for, for example, a copying machine, a printer, or a facsimile.
[0002]
[Prior art]
In an image processing apparatus such as a digital copying machine, even when a copy image of the same document is output due to a change in the state of the internal mechanism of the document reading device (document scanner) or image forming device (printer) over time, The output image may be different. The fidelity of image duplication is strict in an image that requires gradation such as a photographic image, and when a color image is formed, a quality much higher than that of a monochrome image is required. In order to solve this problem, it was necessary to calibrate the apparatus.
[0003]
[Patent Document 1] Japanese Patent Laid-Open No. 9-307750 discloses a predetermined test chart printed out from an image forming apparatus, and the read out test chart is read out by the image reading apparatus, whereby the reading characteristics and image forming of the image reading apparatus are read out. Image processing characteristics relating to a combination of recording characteristics of the image device are detected, and image adjustment data (printer gamma conversion data) for performing optimum processing is automatically generated and output to the image forming device using it. A process for correcting image data is described.
[0004]
In addition, double-sided printing that transfers images onto both front and back sides of paper is used. As a transfer method, a first image is transferred and fixed on the first surface (front surface) of a recording medium, and then a double-side reversing device or the like is used. In general, an image forming process of two-step paper feeding is performed in which the front and back sides of the recording medium are reversed and fed again to the transfer unit, and the second image is transferred and fixed on the second side (back side). However, in this double-sided printing, a double-side reversing device or the like is indispensable, and it cannot be denied that the discharge of the first print on both sides is delayed.
[0005]
In Japanese Patent Laid-Open No. 10-268664, image forming mechanisms for forming toner images of Y, M, C, and K colors are arranged around the photosensitive drum, and the photosensitive drum is arranged on the photosensitive drum. , Y, M, C, and K toner images are superimposed to form a first color visible image for printing on the back side of the paper, which is transferred to a transfer belt facing and in contact with the photosensitive drum, and further on the photosensitive drum. Forming a second color visible image for printing on the front side of the paper, and passing the paper between the photosensitive drum and the transfer belt, so that the first color visible image and the second color visible image are simultaneously applied to the back surface and the front surface of the paper. A color imaging device having a double-sided printing function for transfer is described. According to this, there is no double-sided reversing mechanism, and double-sided printing is completed by feeding one stroke. Therefore, it is possible to speed up double-sided printing.
[0006]
[Patent Document 3] Japanese Patent Laid-Open No. 2000-10381 discloses a revolver equipped with developing devices for forming Y, M, C, and K color toner images, and sequentially superimposing the color toner images on a photosensitive drum. The first color visible image is formed, transferred to a primary transfer belt that is in contact with and in contact with the photosensitive drum, transferred to the secondary transfer belt, and further onto the photosensitive drum, a second paper for surface printing. A color visible image is formed and transferred to the primary transfer belt, and the paper is passed between the primary transfer belt and the secondary transfer belt so that the first color visible image and the second color visible image are simultaneously applied to the back surface and the front surface of the paper. A color imaging device having a double-sided printing function for transfer is described. Also by this, there is no double-sided reversing mechanism, and double-sided printing is completed by feeding one stroke.
In FIG. 11 of Japanese Patent Laid-Open No. 2002-116679, each developing device for forming Y, M, C, and K color toner images is mounted on a revolver, and each color toner image is placed on a photosensitive drum. A first color visible image is formed by sequentially overlapping, and this is transferred to a transfer belt facing and contacting the photosensitive drum, and further, a second color visible image for paper surface printing is formed on the photosensitive drum, A color image forming apparatus having a duplex printing function is described in which a sheet is passed between a photosensitive drum and a transfer belt, and a first color developed image and a second color developed image are simultaneously transferred to the back and front surfaces of the sheet. . Also by this, there is no double-sided reversing mechanism, and double-sided printing is completed by feeding one stroke.
[0007]
On the other hand, in recent digital copying machines, the amount of copy per job is increasing, so the time until the end of the job is shortened by increasing the speed, but the processing amount in one device is There is a limit. Therefore, for example, as a system for efficiently processing 100 copies from one copy original, a plurality of image forming apparatuses such as digital copying machines are connected via a communication line, and printing is performed in parallel. A copy operation using a so-called connection mode is known.
[0008]
[Patent Document 5] Japanese Patent Laid-Open No. 5-304575 discloses that, in order to complete mass copying in a single time, when an image of an original is read by one copying machine, image data is transmitted to another copying machine and a plurality of copying is performed. A digital copying apparatus that makes the same copy with a copying machine is described.
[0009]
In particular, since the printing speed of color printing is slower than that of a single black color, it is desired to print in parallel by distributing the required number of copies with a plurality of color copiers or printers using the connection mode.
[0010]
[Problems to be solved by the invention]
In such connection mode image formation, depending on the combination of the image reading device of the image data transmission side copying machine and the image forming device of the receiving side copying machine, the quality of the printed image may be deteriorated, particularly in color printing. Image quality is likely to deteriorate.
[0011]
Recently, there is an image reading apparatus capable of double-sided reading, which is provided with an image pickup apparatus for reading a front side and a back side of a document, and using a transfer belt as described in Patent Documents 2 to 4 described above. There are two-sided printing image forming apparatuses. However, the image reading apparatus has different front side reading characteristics and back side reading characteristics, and the two-sided printing image forming apparatus has image forming characteristics for the front side (first side) and the back side (second side). The image forming characteristics for the surface) are also different, and the copy mode is a combination of an image reading apparatus having a double-sided reading function and an image forming apparatus having a double-sided printing function using a transfer belt. There are four types: front side scanning-printing on the back side of the paper, scanning on the back side of the document-printing on the front side of the paper, scanning on the back side of the document-printing on the back side of the paper, and the image reproduction (copying) characteristics differ in each mode. Deterioration is considered to be. When this image processing apparatus having the double-sided copying function is connected to a linked printing system, the combined mode of coupling of a copying machine and a printer becomes complicated in this system, and there is a high possibility that image quality will deteriorate. It becomes difficult to set a connection mode for obtaining a high-quality printout image, that is, to select a copier or a printer that shares the printout, and to select each mode described above.
[0012]
The first object of the present invention is to obtain a high-quality print image even in linked printing, and a second object is to facilitate the setting of a linked mode for that purpose.
[0013]
[Means for Solving the Problems]
(1) An image forming apparatus (100) for printing an image represented by image data on a recording medium;
Means (131) for printing a reference image (AcP) on a recording medium with the imaging device;
Communication means (ACP) for receiving image data of the document reading device of the remote image processing device (B);
Based on the image data received by the communication means (ACP) and read from the reference image recording medium by the document reading device, the image forming device (100) prints the image data of the document reading device with high image quality. Means for generating and storing adjustment data (IPP) for correcting the image data to be used; and
An image quality processing means (IPP) that is received by the communication means (ACP) and corrects the image data of the document reading device (B) using the adjustment data and supplies the corrected image data to the image forming device (100);
An image processing apparatus (A).
[0014]
In addition, in order to make an understanding easy, the code | symbol of the corresponding element or the corresponding matter of the Example which is shown in drawing and mentioned later in parentheses was added as an example for reference. The same applies to the following.
[0015]
According to this, the document reading means of the image processing apparatus (B) that can serve as the image data source by the connected printing on the recording medium on which the image forming means (100) of the image processing apparatus (A) has printed the reference image (Acp). When the image (reference image) of the recording medium is read and the image data is transmitted from the image processing apparatus (B) to the communication means (ACP), the means (IPP) for generating adjustment data Adjustment data for the image forming apparatus (100) to print data with high image quality is generated and stored.
[0016]
Thereafter, for linked printing, the document reading device of the image processing device (B) reads the image of the document, and the image data is transferred from the image processing device (B) to the communication means (ACP) of the image processing device (A). The image quality processing means (IPP) corrects the received image data using the adjustment data. As a result, the image data of the document reading device of the image processing device (B) is corrected to image data for the image forming device (100) to print with high image quality, and the image forming device (100) has high image quality. Print out.
[0017]
When the adjustment data is generated as described above, it is only necessary to designate linked printing for transferring the image data from the document reading apparatus of the image processing apparatus (B) to the image forming apparatus (A) and printing out the image forming apparatus (A). Thus, a high-quality printed image can be obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
(2) The original document reading device (210, 230) that reads the image of the document; and means (220, 80j, 80k in FIG. 12) for designating transmission of the image data of the document read by the document reading device; The communication means (ACP) includes an image processing apparatus (B) designated by the transmission designation means (220, 80j, 80k in FIG. 12), and the original document reading apparatus (210, 230). The image processing apparatus according to (2), wherein the read image data is transmitted.
[0019]
According to this, using the designation means (220, 80j, 80k in FIG. 12) in the image processing apparatus (A), the image data of the original document reading means (210, 230) is transferred to another image processing apparatus (B). It is possible to execute a concatenation mode for sending to and printing. A reference image (Acp) is printed in advance in another image processing apparatus (B) that can be a transfer target of the image data, and the recording medium is read by the original document reading means (210, 230). Is sent to the image processing apparatus (B), and adjustment data is generated and held in the other image processing apparatus (B), so that other image processing can be performed from the original document reading means (210, 230). The print image of the concatenation printing that sends the image data to the apparatus (B) becomes high quality. A high-quality print image can be obtained simply by designating linked printing with the designation means (220, 80j, 80k in FIG. 12). In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0020]
(3) Document reading device (210, 230) for reading an image of the document;
Based on the image data read by the document reading device (210, 230) of the reference image printed by the image forming device of the remote image processing device (B), the image forming device converts the image data of the document reading device. Means (IPP) for generating and storing adjustment data for correcting image data used for printing with high image quality;
An image quality processing means (IPP) for correcting image data read by the original reading device (210, 230) using the adjustment data;
Means (220, 80j, 80k in FIG. 12) for designating transmission of image data of a document read by the document reading device (210, 230);
Communication means (ACP) for sending the image data corrected by the image quality processing means (IPP) to the image processing apparatus (B) designated by the transmission designation means (220);
An image processing apparatus (A).
[0021]
According to this, the image data of the original reading means (210, 230) is transmitted to the other image processing apparatus (B) using the designation means (220, 80j, 80k in FIG. 12) in the image processing apparatus (A). You can execute the connected mode to print. A reference image (Acp) is printed in advance in another image processing apparatus (B) that can be a transfer target of image data, the recording medium is read by the original reading means (210, 230), and the image data is read by the image processing apparatus ( B) generates and stores adjustment data for printing with high image quality.
[0022]
Thereafter, for linked printing, an image of the original is read by the original reading device of the image processing apparatus (A), the image data is corrected by the image quality processing means (IPP), and the transmission specifying means (ACP) is sent by the transmission specifying means (ACP). 220), the corrected image data is transmitted to the image processing apparatus (B) designated.
[0023]
As a result, the image data of the document reading device (210, 230) of the image processing apparatus (A) is corrected to image data for the image processing apparatus (B) to print with high image quality, and the image processing apparatus (B) is corrected. Sent and printed there.
[0024]
When the adjustment data is generated as described above, the image data is transferred from the document reading device (210, 230) of the image processing device (A) to the image processing device (B) and printed out by the image processing device (B). High-quality printed images can be obtained simply by specifying printing. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0025]
(4) The means (IPP) for generating the adjustment data reads the original based on the image data read by the first side and second side reading means on the recording medium of the reference image (AcP). Generating respective adjustment data for reading the first surface and the second surface for correcting the image data of the first surface and the second surface reading means of the apparatus to image data for the image forming device to print with high image quality;
The image quality processing means (IPP) corrects each image data read by the first side and second side reading means of the document reading device using each adjustment data for reading the first side and second side; The image processing apparatus according to (1), (2), or (3).
[0026]
According to this, the first side reading adjustment data in the connection mode that is a combination of the image reading of the first side reading unit of the original reading device and the printing of the image forming device is generated, and the second side of the original reading device is generated. Second surface reading adjustment data in a connection mode that is a combination of image reading by the surface reading means and printing by the image forming device is generated.
[0027]
When the adjustment data is generated as described above, the image data of the double-sided document reading apparatus of the image processing apparatus (A) is transferred to the image forming apparatus (B) and printed out by the image forming apparatus of the image forming apparatus (B). By simply specifying printing, it is possible to obtain a high-quality printed image obtained by scanning both sides of the original. That is, it is easy to set the connection mode for front side reading, back side reading, or double sided reading, which can obtain a high-quality printed image.
[0028]
(5) The image forming apparatus includes an image forming unit (1-12) for forming a visible image representing an image represented by the image data, and a visible image carrying unit (13) to which the image formed by the image forming unit is transferred. ), The developed image formed by the image forming means (1 to 12) after the transfer on one side of the recording medium, and the visible image transferred to the visible image holding means (13) on the other side of the recording medium. In the case of double-sided printing based on image transfer means (17, 19, image storage means (MEM, HDD, ACP) for storing image data, image data stored in the image storage means) A first visible image is formed by the means (1-12) and transferred onto the transfer surface of the visible image holding means (13). After the first visible image, the second visible image is created by the imaging means (1-12). A first visible image formed by forming an image and transferring the second visible image to one side of the recording medium and to the visible image carrying means (13) In the case of single-sided printing after transferring to the other surface of the recording medium, a visible image is formed by the imaging means (1-12) and directly or transferred to the visible image holding means (13). A printing control means (131) for transferring to a recording medium, and printing of a reference image in a first transfer mode in which a visible image is formed and transferred directly to the recording medium by the imaging means (1-12); The reference image is printed on the recording medium in the second transfer mode in which a visible image is formed by the image forming means (1-12) and transferred to the visible image carrying means and then transferred to the recording medium. Means (131) for providing;
The means (IPP) for generating the adjustment data is based on the image data obtained by reading the recording medium of the first and second transfer modes of the reference image, and the image data of the original reading device that has read the image data. Generating respective adjustment data for the first and second transfer modes, which the apparatus corrects to image data for high-quality printing in the first and second transfer modes;
The image quality processing means (IPP) uses the adjustment data for the first transfer mode when printing in the first transfer mode, and the second transfer mode when printing in the second transfer mode. Correction using the adjustment data for
The image processing apparatus according to any one of (1) to (4) above.
[0029]
According to this, the reference image (Acp) is printed in the first transfer mode, and the image is read by the document reading device, thereby combining the image reading of the document reading device and the printing in the first transfer mode of the image forming device. Adjustment data for the first transfer mode in the connected mode is generated. Similarly, the reference image (Acp) is printed in the second transfer mode, and the image is read by the document reading device, thereby combining the image reading of the document reading device and the printing in the second transfer mode of the image forming device. Adjustment data for the second transfer mode in the connected mode is generated.
[0030]
When the adjustment data is generated as described above, a high-quality print image can be obtained simply by transferring the image data of the document reading device to the image forming device and designating linked printing for printing in the first transfer mode or the second transfer mode. Is obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0031]
(6) The means for designating transmission (220, 80j, 80k in FIG. 12) designates transmission to an image processing apparatus that has not generated adjustment data for image data generated by the original document reading apparatus. The image forming apparatus according to (2) or (3) above. According to this, the user knows that the adjustment data needs to be generated by the alarm (FIG. 13). If high quality linked printing is desired, the adjustment data described in (1) or (3) above may be generated.
[0032]
(7) The means for designating transmission (220, 80j, 80k in FIG. 12) designates transmission to an image forming apparatus whose adjustment data is generated for the image data generated by the original document reading means. The image processing apparatus according to (2), (3) or (6) above.
[0033]
(8) Image forming means (1-12) for forming a visible image representing the image represented by the print image data; image quality for correcting the image data to print image data suitable for the image forming means (1-12) An image forming apparatus comprising: a processing unit (IPP); and a communication unit (ACP) that provides received image data to the image quality processing unit (IPP).
Means (131) for printing a reference image (Acp) on a recording medium by the image forming means (1-12); and
Based on the image data read from the recording medium of the reference image (AcP) received by the communication means (ACP), the image data of the original reading means (B) that has been read is converted into the image forming means (1-12). ) Includes means for generating adjustment data (IPP) for correcting the image data for printing for printing with high image quality,
The image quality processing means (IPP) corrects the image data of the original reading means (B) to the print image data using the adjustment data;
An image forming apparatus (A).
[0034]
According to this, the recording medium on which the printing means (131) of the image forming apparatus (A) prints the reference image (Acp) is used as a copy machine or an image reading apparatus that can serve as an image data source by linked printing. When the image (reference image) of the recording medium is read by carrying to the reading means (B) and the image data is transmitted to the communication means (ACP), the means (IPP) for generating adjustment data receives the image data. The image forming means (1-12) generates adjustment data to be corrected to print image data for printing with high image quality.
[0035]
Thereafter, when the original reading means (B) reads an image of the original and transmits the image data to the communication means (ACP) of the image forming apparatus (A) for linked printing, the image quality processing means (IPP) However, the image data of the document reading means (B) is corrected to the image data for printing using the adjustment data. As a result, the image data of the document reading means (B) is corrected to print image data for the image forming means (1-12) to print with high image quality, and the image forming means (1-12) is corrected to high image quality. Print out the image. When the adjustment data is generated as described above, the image data is transferred from the document reading unit (B) to the image forming apparatus (A), and only the linked printing to be printed out by the image forming apparatus (A) is designated. A quality printed image is obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0036]
(9) The adjustment data generation means (IPP) reads each reference image (AcP) recording medium received by the communication means (ACP) by the first surface and the second surface reading means. Image data for printing by the image forming means (1-12) to print the image data of the first side and second side reading means of the original reading means (B) that has been read based on Each adjustment data for reading the first surface and the second surface to be corrected to
The image quality processing means (IPP) uses the adjustment data for reading the first and second surfaces of the image data read by the first and second surface reading means of the document reading means (B). The image forming apparatus according to (8), wherein the image data for printing is corrected.
[0037]
According to this, the reference image (Acp) is printed by the printing means (131) of the image forming apparatus (A), and the image on the recording medium is read by the first surface reading means of the document reading means (B). By reading and transmitting to the communication means (ACP), in the connected mode, which is a combination of the image reading of the first surface reading means of the document reading means (B) and the printing of the image forming means (1-12). One-side reading adjustment data is generated. Similarly, the image on the recording medium is read by the second surface reading unit of the document reading unit (B) and transmitted to the communication unit (ACP), so that the second surface reading unit of the document reading unit (B) Second-side reading adjustment data in a connection mode that is a combination of image reading and printing by the image forming means (1 to 12) is generated.
[0038]
When the adjustment data is generated as described above, the image data is transferred from the document reading unit (B) to the image forming apparatus (A), and only the linked printing to be printed out by the image forming apparatus (A) is designated. A quality printed image is obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0039]
(10) Image storage means (MEM, HDD, ACP) for storing image data;
A visible image carrying means (13) to which a visible image formed by the imaging means is transferred;
Means (17, 19) for transferring the visible image formed by the image forming means after the transfer to one surface of the recording medium and the visible image transferred to the visible image holding means to the other surface of the recording medium. );and,
Based on the image data stored in the image storage means (MEM, HDD, ACP), in the case of duplex printing, the image forming means (1-12) forms a first visible image and the visible image holding means. (13) the image is transferred onto the transfer surface, the second image is formed by the image forming means (1-12) after the first image, and the second image is formed on one surface of the recording medium; The first visible image transferred to the visible image carrying means (13) is transferred to the other surface of the recording medium, and in the case of single-sided printing, a visible image is formed by the imaging means (1-12). A printing control means (131) for transferring directly to the visible image carrying means (13) and then transferring to the recording medium;
The means (131) for printing the reference image (Acp) on a recording medium forms a visible image by the image forming means (1-12) and directly transfers it to the recording medium (Acp). ) And a reference image (Acp) in a second transfer mode in which a visible image is formed by the imaging means (1-12) and transferred to the visible image carrier means (13) and then transferred to a recording medium. Print and do;
The means (IPP) for generating the adjustment data is based on the image data read by the communication means (ACP) and read from the recording media in the first and second transfer modes of the reference image (AcP). First and second image data of the original reading means (B) that has been read are corrected to image data for printing by the image forming means (1 to 12) for high-quality printing in the first and second transfer modes. Generate each adjustment data for transfer mode;
The image quality processing means (IPP) uses the adjustment data for the first transfer mode when printing in the first transfer mode and the image data of the document reading means (B) when printing in the second transfer mode. The image forming apparatus according to (8), wherein the image data for printing is corrected using the adjustment data for the two transfer mode.
[0040]
According to this, the reference image (Acp) is printed in the first transfer mode by the printing means (131) of the image forming apparatus (A), the image is read by the document reading means (B), and the communication means ( ACP) is used to adjust the connection mode for the first transfer mode, which is a combination of the image reading of the document reading means (B) and the printing of the first transfer mode of the image forming means (1-12). Data is generated. Similarly, the reference image (Acp) is printed in the second transfer mode, and the image is read by the document reading unit (B) and transmitted to the communication unit (ACP), whereby the image reading unit (B) reads the image. And adjustment data for the second transfer mode in the connection mode, which is a combination of the image forming means (1-12) and the second transfer mode printing.
[0041]
When the adjustment data is generated as described above, the image data is transferred from the document reading unit (B) to the image forming apparatus (A), and only the linked printing to be printed out by the image forming apparatus (A) is designated. A quality printed image is obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0042]
(10a) Image storage means for storing image data (MEM, HDD, ACP);
A visible image carrying means (13) to which a visible image formed by the imaging means is transferred;
Means (17, 19) for transferring the visible image formed by the image forming means after the transfer to one surface of the recording medium and the visible image transferred to the visible image holding means to the other surface of the recording medium. );and,
Based on the image data stored in the image storage means (MEM, HDD, ACP), in the case of duplex printing, the image forming means (1-12) forms a first visible image and the visible image holding means. (13) the image is transferred onto the transfer surface, the second image is formed by the image forming means (1-12) after the first image, and the second image is formed on one surface of the recording medium; The first visible image transferred to the visible image carrying means (13) is transferred to the other surface of the recording medium, and in the case of single-sided printing, a visible image is formed by the imaging means (1-12). A printing control means (131) for transferring directly to the visible image carrying means (13) and then transferring to the recording medium;
The means (131) for printing the reference image (Acp) on a recording medium forms a visible image by the image forming means (1-12) and directly transfers it to the recording medium (Acp). ) And a reference image (Acp) in a second transfer mode in which a visible image is formed by the imaging means (1-12) and transferred to the visible image carrier means (13) and then transferred to a recording medium. Print and do;
The adjustment data generation means (IPP) reads each recording medium in the first transfer mode of the reference image (AcP) received by the communication means (ACP) by the first side and second side reading means. A printing image for the image forming means (1-12) to print the image data of the first side and the second side reading means of the original reading means (B) that has been read based on the data with high image quality. The adjustment data for the first surface reading first transfer mode and the second surface reading first transfer mode to be corrected to data is generated, and the recording medium in the second transfer mode of the reference image (AcP) is set to the first recording medium. Based on the image data read by the surface and second surface reading means, the image data of the first surface and the second surface reading means of the original reading means (B) that has been read is converted into the image forming means (1-12). ) Print image data for printing with high image quality. It generates the adjustment data for the first surface reading second transfer mode and the second surface reading second transfer mode for correcting the data;
The image quality processing means (IPP) reads the image data read by the first side and second side reading means of the original reading means (B) for the first side reading first transfer mode and the second side reading first. Each image data for printing is corrected using each adjustment data for transfer mode or each adjustment data for first side reading second transfer mode and second side reading second transfer mode; Image forming apparatus.
[0043]
According to this, the reference image (Acp) is printed in the first transfer mode by the printing means (131) of the image forming apparatus (A), and the image on the recording medium is printed on the first reading means (B). Reading by the first side reading means and transmitting to the communication means (ACP), the image reading of the first side reading means of the original reading means (B) and the printing in the first transfer mode of the image forming means (1-12). The adjustment data for the first surface reading first transfer mode in the connection mode that is a combination of the first and second modes is generated. Similarly, the image on the recording medium is read by the second surface reading unit of the document reading unit (B) and transmitted to the communication unit (ACP), so that the second surface reading unit of the document reading unit (B) Adjustment data for the second surface reading first transfer mode in the connection mode, which is a combination of image reading and printing in the first transfer mode of the image forming means (1-12), is generated.
[0044]
Similarly, the reference image (Acp) is printed in the second transfer mode by the printing means (131) of the image forming apparatus (A), and the image on the recording medium is printed on the first surface of the document reading means (B). Reading by the reading means and transmitting to the communication means (ACP), the image reading of the first surface reading means of the document reading means (B) and the printing in the second transfer mode of the image forming means (1-12). Adjustment data for the first surface reading second transfer mode of the combined connection mode is generated. Similarly, the image on the recording medium is read by the second surface reading unit of the document reading unit (B) and transmitted to the communication unit (ACP), so that the second surface reading unit of the document reading unit (B) Adjustment data for the second surface reading second transfer mode in the connection mode, which is a combination of image reading and printing in the second transfer mode of the image forming means (1-12), is generated.
[0045]
When the adjustment data is generated as described above, the image data is transferred from the document reading unit (B) to the image forming apparatus (A), and only the linked printing to be printed out by the image forming apparatus (A) is designated. A quality printed image is obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0046]
(11) a document reading unit (210, 230) on its own side that reads an image of the document; and
Means (220, 80j, 80k in FIG. 12) for designating transmission of image data of the original read by the original reading means (210, 230);
The communication means (ACP) transmits the image data read by the original document reading means (210, 230) to the image forming apparatus designated by the transmission designation means;
The image forming apparatus as described in any one of (1) to (3a) above.
[0047]
According to this, using the designation means (220, 80j, 80k in FIG. 12) in the image forming apparatus (A), the image data of the original document reading means (210, 230) is transferred to another image forming apparatus (B). It is possible to execute a concatenation mode for sending to and printing. A reference image (Acp) is printed in advance in another image forming apparatus (B) that can be a transfer target of image data, and the recording medium is read by the original document reading means (210, 230). Is sent to the image forming apparatus (B) and the adjustment data is generated in the other image forming apparatus (B), so that the document reading means (210, 230) on the self-side forms another image forming apparatus (B). The print image of the concatenation printing that sends the image data to) becomes high quality. A high-quality print image can be obtained simply by designating linked printing with the designation means (220, 80j, 80k in FIG. 12). In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[0048]
(11a) The self-side document reading means (210, 230) reads the first surface reading means (207 of 210) and the second surface (back surface) for reading the image on the first surface (front surface) of the same document. The image forming apparatus according to (4), further including a two-side reading unit (208 of 230). According to this, it is possible to simultaneously read both sides of a double-sided document in the image forming apparatus (A), and to perform double-sided image connection printing.
[0049]
(12) The means for designating transmission (220) warns when transmission to an image forming apparatus that has not generated adjustment data for image data generated by the original document reading means (210, 230) is designated. The image forming apparatus according to (11) above. According to this, the user knows that the adjustment data needs to be generated by the alarm. If high quality linked printing is desired, the adjustment data described in (8) to (11a) above may be generated.
[0050]
(13) The means for designating transmission (220) warns when transmission to an image forming apparatus having a generation time of adjustment data for image data generated by the original document reading means (210, 230) is designated. The image forming apparatus according to (11) or (12). The image reading characteristics and the printing characteristics vary with time. In particular, the printing characteristics tend to vary. If the adjustment data is generated at an old time, the image quality of the linked printing may be lowered. In this case, it can be seen that the adjustment data needs to be regenerated by an alarm. If high-quality linked printing is desired, the adjustment data described in (9) to (10a) above may be generated again.
[0051]
(14) The image forming means (1 to 12) is color image forming means (ad) that forms a color image formed by superimposing a plurality of different color images; any one of (8) to (13) above The image forming apparatus according to one. According to this, the effects described in the above (8) to (13) can be similarly obtained in color double-sided, single-sided printing or copying.
[0052]
(15) The image forming means (1-12) includes a plurality of image forming units (ad) arranged in tandem and a first transfer medium (7) onto which the visible images formed by the image forming units are sequentially superimposed and transferred. The image forming apparatus according to any one of (8) to (14), including: According to this, since the visible images created by the plurality of image forming units (ad) arranged in tandem are transferred onto the first transfer medium (7), the image forming speed of the color visible image can be increased. I can do it. In addition, since the speed of double-sided printing can be increased, color image printing or copying can be speeded up.
[0053]
(16) A first image carrier (1), a second image carrier (7), and a third image carrier (13), and the first image carrier to the second image carrier. And a visible image transferred from the second image carrier to the third image carrier is transferred to one first surface of the recording medium, and the second image carrier is transferred from the first image carrier. An image forming means (100) capable of transferring a visible image to both sides of the recording medium by transferring the visible image transferred to the body to the other second surface of the recording medium, and a color for generating RGB image data of the read original A document reading apparatus (210, 220) capable of reading both sides simultaneously, an image quality processing means (IPP) for correcting RGB image data to KCMY image data used for image formation by the image forming means (100), and a communication line Image data is given to the image quality processing means (IPP) and the original A communication means (ACP) for sending image data of a document read by the taking device (210, 220) to a communication line, and a means (220) for designating the communication means (ACP) to transmit image data for linked printing. , Transfer of the reference image to the first or second surface of the image forming means (100) and other color reading device that transmits image data via the communication line simultaneously. An adjustment data generating means (IPP) for automatically adjusting images in accordance with respective combinations of read image data of the recording medium to which the reference image is transferred, on the front surface or back surface reading means, and storing the image adjustment data; Before converting image data of a document sent from a reading device into KCMY image data used for image formation by the image forming means (100) using the image adjustment data An image forming apparatus including an image quality processing unit (IPP), a.
[0054]
According to this, it is possible to always obtain an output image having the same color and image quality regardless of the combination of the reading device and the surface of the image output device during linked copying.
[0055]
(17) A warning that the user does not hold the image adjustment data when an output is made using a combination of the surface of the document reading device that does not hold the image adjustment data and the surface of the image forming device at the time of linked printing. The image forming apparatus as described in (16) above, wherein the output is disabled or the output is disabled. According to this, in the case of a combination of the surface of the document reading apparatus and the surface of the image forming apparatus that does not hold image adjustment data at the time of linked printing, the image is not output or the user is warned. It is possible to prevent a bad image that has not been adjusted from being output.
[0056]
(18) At the time of linked printing, a warning is given to the user when an attempt is made to output a combination of the surface of the document reading device and the surface of the image forming device that has not been subjected to automatic image adjustment for a certain period, or The image forming apparatus according to (16) or (17), wherein output is disabled. According to this, at the time of linked printing with a combination of the surface of the document reading apparatus and the surface of the image forming apparatus holding inappropriate image adjustment data, image output is not performed or a warning is given to the user. It is possible to prevent a defective image from being output due to incomplete image adjustment.
[0057]
Other objects and features of the present invention will become apparent from the following description of embodiments with reference to the drawings.
[0058]
【Example】
FIG. 1 shows a printing system according to an embodiment of the present invention. This printing system has a copying function for reading and printing a document image, a function for reading a document image and transferring the image data to another apparatus, and a function for printing the transferred image. C, a document scanner G having a function of reading a document image and transferring it to another apparatus, printers D, E, F having a function of receiving and printing image data, and instructing transfer of image data PCs with functions are connected to each other via a communication medium, and image data is transferred between the devices to print out the images. At least one copier or document scanner is used. Thus, it is possible to perform linked printing in which an original image is read and the printing process is shared by at least two copying machines or printers.
[0059]
The copiers A, B, and C have an image input / output function and a communication function of an existing composite function (copy, facsimile, printer, scanner, etc.), a connection function with a local network LAN (Local Area Network), and a server. It has a function and a function for displaying operation screens of multiple applications. Other printers D, E, F, document scanner G, and personal computer PC, which is a print command device, also have a function of connecting to a network LAN. The printers D, E, and F can receive print information from other devices via the network LAN and print them out. The document scanner G can read a document image and transfer the document information to another device via the network LAN. The personal computer PC can obtain the document information from other devices via the network LAN, and can transfer the document information held by itself to the other devices.
[0060]
In addition, the personal computer F, which is a print command device, remotely operates the multifunctional copying machines A to C or the document scanner G to read the document image, and the multifunctional copying machines A to C, personal computers (the personal computer and other personal computers). "Network image input / output application" (application program :) that is stored in a personal computer), document scanner G or printers D to F, and specifies the stored document information file and prints out with the multifunction copying machines A to C and printers D to F Application software) is loaded (loaded, set up).
[0061]
In the device group shown in FIG. 1, the multi-function copying machines A to C each have a communication terminal and a facsimile controller (FCU) connected to a facsimile communication line and can individually send and receive a facsimile. The other printers D to F, the document scanner G, and the personal computer PC do not have a facsimile controller (FCU), but transfer document information for transmission to the multifunction copier A, B, or C via the network LAN. Facsimile transmission is possible from the transfer destination copier. In addition, the multi-function copying machines A to C can transfer the received document information to other copying machines, printers or personal computers during reception, and store them in the transfer destination image memory. The stored document information can be printed out by itself or other devices having a print function. The personal computer PC also serves as a client when the user uses a device connected to the network LAN.
[0062]
FIG. 2 is an enlarged view of the multi-function copying machine A. The copier A is a multi-function full color digital copier. The full-color copying machine A is roughly constituted by units of an automatic document feeder (ADF) 230, an operation board 220, a color scanner 210, and a color printer 100. Note that the operation board 220 and the color scanner 210 with the ADF 230 are units that can be separated from the printer 100. The color scanner 210 includes a control board having a power device driver, sensor input, and controller. Communication with the image data processing device ACP (FIG. 5) of the control board in the apparatus is performed directly or indirectly to read the document image under timing control.
[0063]
A LAN (Local Area Network) connected to a personal computer PC is connected to the image data processing apparatus ACP (FIG. 5), and a telephone line PN (facsimile communication line) is connected to the facsimile control unit FCU (FIG. 5). The exchange PBX is connected. The printed paper of the color printer 100 is discharged to the paper discharge stack 26 (FIG. 3).
[0064]
FIG. 3 shows the mechanism of the color printer 100. The color printer 100 of this embodiment is a laser printer. The laser printer 100 includes four sets of toner image forming units a to d for forming images of each color of magenta (M), cyan (C), yellow (Y), and black (black: K). Are arranged in this order along the moving direction (lower right to upper left direction y in the figure). That is, it is a four-drum type full-color image forming apparatus.
[0065]
A static eliminating device 5, a cleaning device 4, a charging device 2, and a developing device 3 are arranged on the outer peripheral portion of the photosensitive member 1, which is a first image carrier that is rotatably supported and rotates in the direction of the arrow. A space for storing optical information emitted from the exposure device 6 is secured between the charging device 2 and the developing device 3. There are four photosensitive members 1 (a, b, c, d), and the components for image formation provided around each are the same. The color of the color material (toner) handled by the developing device 3 is different.
[0066]
The photoconductor 1 as the first image carrier is a photoconductor in which an organic semiconductor layer as a photoconductive material is provided on the surface of an aluminum cylinder having a diameter of about 30 to 100 mm. Part of it is in contact with the first transfer belt 7 which is the second image carrier. A belt-like photoreceptor 1 can also be employed.
[0067]
The first transfer belt 7 is supported and stretched between the rotating rollers 8, 9, and 10 so as to be movable in the direction of the arrow. On the back side (inside the loop), the first transfer means 11 is attached to the photoreceptor 1. It is deployed in the vicinity. A cleaning device 12 for the first transfer belt is disposed outside the belt loop. Unnecessary toner remaining on the surface after the transfer from the first transfer belt 7 is wiped off.
[0068]
The exposure device 6 irradiates the uniformly charged surface of the photoconductor as a latent image with optical information corresponding to full-color image formation by a known laser system. An exposure apparatus comprising an LED array and an image forming means can also be employed. The first transfer belt 7 is a belt having a base of a resin film or rubber having a base thickness of 50 μm to 600 μm, and has a resistance value capable of transferring toner from the photoreceptor 1.
[0069]
On the right side of the first transfer belt 7 in FIG. 3, a second transfer belt 13 as a third image carrier is provided. The second transfer belt 13 is supported and stretched between the rotary rollers 14, 15 and 16 so as to be movable in the direction of the arrow, and a second transfer means 17 is provided on the back side (inside the loop). Outside the belt loop, a cleaning device 18 for the second transfer belt, a charger 19 and the like are provided. After the toner is transferred to the paper, the cleaning device 18 wipes away the remaining unnecessary toner.
[0070]
The first transfer belt 7 and the second transfer belt 13 are brought into contact with each other by the second transfer means 17, the roller 16, and the roller 8 supporting the first transfer belt 7, thereby forming a predetermined transfer nip. The second transfer belt 13 is a belt having a base of a resin film or rubber having a base thickness of 50 μm to 600 μm, and is a belt having a resistance value capable of transferring toner from the first transfer belt 7.
[0071]
The paper 20 as a recording medium is stored in the paper feed cassettes 21 and 22 in the lower part of the figure, and the uppermost paper is conveyed one by one by the paper feed rollers 31 or 32 to the registration rollers 33 through a plurality of paper guides. Is done. Above the second transfer belt 13, a fixing device 23, a paper discharge guide 24, a paper discharge roller 25, and a paper discharge stack 26 are arranged.
[0072]
A storage section 27 that can store replenishment toner is provided above the first transfer belt 7 and below the paper discharge stack 26. The toner has four colors, magenta, cyan, yellow, and black, and is in the form of a cartridge 28. The developing device 3 corresponding to the corresponding color is appropriately supplied by a powder pump or the like.
[0073]
The frame 29, which is a part of the main body, has a structure that can be pivoted and opened around the opening / closing support shaft 30. Therefore, the conveyance path of the recording medium is greatly opened to facilitate the processing of the jammed recording medium (paper). ing.
[0074]
Here, the operation of each unit during duplex printing will be described. First, image formation by the photosensitive member 1 is performed. That is, by the operation of the exposure device 6, light from an LD light source (not shown) passes through an optical component (not shown), and among the photoconductors 1 uniformly charged by the charging device 2, the photoconductor of the image forming unit a. Then, a latent image corresponding to the writing information (information corresponding to the color) is formed. The latent image on the photoreceptor 1 is developed by the developing device 3, and a visible image with toner is formed and held on the surface of the photoreceptor 1. This toner image is transferred by the first transfer means 11 to the surface of the first transfer belt 7 that moves in synchronization with the photoreceptor 1. The remaining toner on the surface of the photoreceptor 1 is cleaned by the cleaning device 4 and discharged by the charge removing device 5 to prepare for the next image forming cycle.
[0075]
The first transfer belt 7 carries the toner image transferred on the surface and moves in the direction of the arrow. A latent image corresponding to another color is written on the photoreceptor 1 of the image forming unit b, and developed with a toner of the corresponding color to become a visible image. This image is superimposed on the visible image of the previous color already on the first transfer belt 7, and finally four colors are superimposed. In some cases, only monochrome black is formed.
[0076]
At this time, the second transfer belt 13 moves in the direction of the arrow in synchronism, and the image created on the surface of the first transfer belt 7 is transferred to the surface of the second transfer belt 13 by the action of the second transfer means 17. The The first and second transfer belts 7 and 13 are moved while the images are formed on the respective photoreceptors 1 of the four image forming units a to d in the so-called tandem format, and the image forming is advanced. Can be shortened.
[0077]
When the first transfer belt 7 moves to a predetermined position, a toner image to be created on another surface of the paper is formed again by the photoconductor 1 in the process as described above, and paper feeding is started. When the paper feed roller 31 or 32 rotates counterclockwise, the uppermost paper 20 in the paper feed cassette 21 or 22 is pulled out and conveyed to the registration roller 33.
[0078]
The toner image on the surface of the first transfer belt 7 is transferred by the second transfer unit 17 to one surface of the sheet fed between the first transfer belt 7 and the second transfer belt 13 through the registration roller 33. Further, the recording medium is conveyed upward, and the toner image on the surface of the second transfer belt 13 is transferred to the other surface of the sheet by the charger 19. At the time of transfer, the sheet is conveyed at a timing so that the position of the image is normal.
[0079]
In this embodiment, the polarity of the toner imaged on the photoreceptor 1 is negative. By applying a positive charge to the first transfer means 11, the toner imaged on the photoreceptor 1 is transferred to the first transfer belt 7. By applying a positive charge to the second transfer unit 17, the toner transferred to the first transfer belt 7 is transferred to the second transfer belt 13. By feeding the paper between the first and second transfer belts 7 and 13 and applying a positive charge to the second transfer means 17, the toner transferred to the first transfer belt 7 is transferred to one surface of the paper, Further, the toner transferred to the second transfer belt 13 is given a positive polarity charge from the transfer charger 19, so that the negative polarity toner on the surface of the second transfer belt 13 is sucked and transferred to the other surface of the sheet. The
[0080]
The paper on which the toner images are transferred on both sides in the above steps is sent to the fixing device 23, where the toner images (both sides) on the paper are melted and fixed at one time, and the upper part of the main body frame is guided by the paper discharge roller 25 through the guide 24. Are discharged to the paper discharge stack 26.
[0081]
As shown in FIG. 3, when the paper discharge units 24 to 26 are configured, the side (page) of the double-sided image that is transferred to the paper later, that is, the surface that is directly transferred from the first transfer belt 7 to the paper is the lower surface. Since the image is placed on the paper discharge stack 26, in order to align the pages, the image of the second page is created first, the toner image is held on the second transfer belt 13, and the first page The image is directly transferred from the first transfer belt 7 to the sheet.
[0082]
The image directly transferred from the first transfer belt 7 to the sheet is a normal image on the surface of the photoconductor, and the toner image transferred from the second transfer belt 13 to the sheet is a reverse image (mirror image) on the surface of the photoconductor. It is exposed as follows. Such image forming order for page alignment and image processing for switching between normal and reverse images (mirror images) are also performed by image data read / write control to the memory MEM by IMAC.
[0083]
After the transfer from the second transfer belt 13 to the paper, a cleaning device 18 including a brush roller, a collection roller, a blade, and the like removes unnecessary toner and paper dust remaining on the second transfer belt 13.
[0084]
In FIG. 3, the brush roller of the cleaning device 18 is in a state separated from the surface of the second transfer belt 13. The structure can swing around the fulcrum 18a and can contact and separate from the surface of the second transfer belt 13. Before the transfer to the paper, the second transfer belt 13 is released when the toner image is carried, and when the cleaning is necessary, the second transfer belt 13 is swung in the counterclockwise direction in FIG. The removed unnecessary toner is collected in the toner storage unit 34.
[0085]
The image forming process in the duplex printing mode in which the “duplex transfer mode” is set has been described above. In the case of duplex printing, printing is always performed by this image forming process. In the case of single-sided printing, there are two types of "single-sided transfer mode by the second transfer belt 13" and "single-sided transfer mode by the first transfer belt 7", and the former single-sided transfer mode using the second transfer belt 13 is set. In this case, a visible image formed by superimposing four colors (or monochromatic black) on the first transfer belt 7 is transferred to the second transfer belt 13 and transferred to one side of the paper. There is no image transfer on the other side of the paper. In this case, there is a printing screen on the upper surface of the printed paper discharged to the paper discharge stack 26.
[0086]
When the single-sided transfer mode using the latter first transfer belt 7 is set, a visible image formed by superimposing four colors (or single color black) on the first transfer belt 7 is transferred to the second transfer belt 13. Without being transferred to one side of the paper. There is no image transfer on the other side of the paper. In this case, there is a print screen on the lower surface of the printed paper discharged to the paper discharge stack 26.
[0087]
FIG. 4 shows a document image reading mechanism of the scanner 210 and the ADF 230 attached thereto. The document placed on the contact glass 231 of the scanner 210 is illuminated by the illumination lamp 232, and the reflected light (image light) of the document is reflected by the first mirror 233 in parallel with the sub-scanning direction y. The illumination lamp 232 and the first mirror 233 are mounted on a first carriage (not shown) that is driven at a constant speed in the sub-scanning direction y. Second and third mirrors 234 and 235 are mounted on a second carriage (not shown) driven in the same direction as the first carriage, and the image light reflected by the first mirror 233 is The light is reflected downward (z) by the second mirror 234, reflected in the sub-scanning direction y by the third mirror 235, converged by the lens 236, irradiated to the CCD 207, and converted into an electrical signal. The first and second carriages are driven forward (original scanning) and backward (return) in the y direction using the traveling body motor 238 as a drive source.
[0088]
The scanner 210 is equipped with an automatic document feeder ADF230. The documents stacked on the document tray 241 of the ADF 230 are fed between the conveyance drum 244 and the pressing roller 245 by the pickup roller 242 and the registration roller pair 243, and are in close contact with the conveyance drum 244 and pass over the reading glass 240. Then, the paper is discharged onto a paper discharge tray 248 serving as a pressure plate below the document tray 241 by the paper discharge rollers 246 and 247. When the image on the surface of the document passes through the reading glass 240, the image is irradiated by the illumination lamp 232 that moves immediately below the image, and the reflected light on the surface of the document is passed through the optical system below the first mirror 233 to the CCD 207. And is photoelectrically converted. That is, it is converted into RGB color image signals. Further, the image on the back side of the document is read and photoelectrically converted by an image pickup device 208 including a light source and an image pickup device. That is, it is converted into RGB color image signals.
[0089]
A white reference plate 239 and a base point sensor 249 for detecting the first carriage are provided between the reading glass 240 and the scale 251 for positioning the document start end. The white reference plate 239 is used for reading a document having a uniform density due to variations in individual light emission intensities of the illumination lamps 232, variations in the main scanning direction, sensitivity variations for each pixel of the CCD 207, and the like. It is prepared to correct the phenomenon that the read data varies (shading correction).
[0090]
FIG. 5 shows the system configuration of the image processing system of the copying machine shown in FIG. In this system, a color document scanner 210 including a reading unit 211 and an image data output I / F (Interface) 212 is connected to an image data interface control CDIC (hereinafter simply referred to as CDIC) of the image data processing apparatus ACP. Yes. A color printer 100 is also connected to the image data processing apparatus ACP. The color printer 100 receives the writing I / F 134 YMCK recording image data from an image data processor IPP (Image Processing Processor; hereinafter simply referred to as IPP) of the image data processing apparatus ACP, and prints it out by the imaging unit 135. The image forming unit 135 is shown in FIG.
[0091]
The image data processing device ACP (hereinafter simply referred to as ACP) includes a parallel bus Pb, an image memory access control IMAC (hereinafter simply referred to as IMAC), an image memory MEM (memory module; hereinafter simply referred to as MEM), and a hard disk device. An HDD (hereinafter simply referred to as HDD), a system controller 31a, a RAM 34, a nonvolatile memory 35, a font ROM 36, a CDIC, an IPP, and the like are provided. A facsimile control unit FCU (hereinafter simply referred to as FCU) is connected to the parallel bus Pb. The operation board 220 is connected to the system controller 31a.
[0092]
The RGB image signals generated by the CCD 207 of the reading unit 211 and the image pickup device 208 of the image reading device 208 of the color original scanner 210 for optically reading the original are processed on the sensor board unit SBU and converted into RGB image data. In addition, shading correction is performed and the data is sent to the CDIC via the output I / F 212.
[0093]
The CDIC performs communication between the output I / F 212, the parallel bus Pb, and the IPP, and the process controller 131 and the system controller 31a that controls the entire ACP with respect to the image data. The RAM 132 is used as a work area for the process controller 131, and the nonvolatile memory 133 stores an operation program for the process controller 131.
[0094]
In addition to the semiconductor memory MEM, there is an HDD for storing a lot of image data. By using the HDD, there is a feature that an external power source is unnecessary and an image can be held permanently. Many original images can be read by a scanner and held in the HDD, and many document images provided by the PC can be held.
[0095]
Image memory access control IMAC (hereinafter simply referred to as IMAC) controls writing / reading of image data and control data to / from MEM and HDD. The system controller 31a controls the operation of each component connected to the parallel bus Pb. The RAM 34 is used as a work area for the system controller 31a, and the nonvolatile memory 35 stores an operation program for the system controller 31a.
[0096]
The operation board 220 inputs processing to be performed by the ACP. For example, the type of processing (copying, facsimile transmission, image reading, printing, etc.), the number of processings, etc. are input. Thereby, the image data control information can be input.
[0097]
The RGB image data read by the scanner 210 and the CCD 207 of the ADF and the imaging device 208 is subjected to image processing for correcting reading distortion such as scanner gamma correction and filter processing by the IPP, and then stored in the MEM. When printing out MEM image data, IPP performs color conversion of RGB signals to YMCK signals, and performs image quality processing such as printer gamma conversion, gradation conversion, and gradation processing such as dither processing or error diffusion processing. The image data after the image quality processing is transferred from the IPP to the writing I / F 134. The writing I / F 134 performs laser control on the gradation processed signal by pulse width and power modulation. Thereafter, the image data is sent to the image forming unit 135, and the image forming unit 135 forms a reproduced image on the transfer paper.
[0098]
Based on the control of the system controller 31a, the IMAC controls the access of image data, MEM, and HDD, develops print data of a personal computer PC (not shown) connected to the LAN (hereinafter simply referred to as PC), Compress / decompress image data for effective use.
[0099]
The image data sent to the IMAC is stored in the MEM or HDD after data compression, and the stored image data is read out as necessary. The read image data is decompressed, returned to the original image data, and returned from the IMAC to the CDIC via the parallel bus Pb. After transfer from the CDIC to the IPP, the image quality processing is performed and the image is output to the writing I / F 134, and a reproduced image is formed on the transfer paper (paper) in the image forming unit 135.
[0100]
In the flow of image data, the functions of the digital multi-function peripheral are realized by the bus control by the parallel bus Pb and the CDIC. Facsimile transmission is performed by performing image processing on the image data read by the scanner 210 and the ADF 230 with the IPP and transferring the image data to the FCU via the CDIC and the parallel bus Pb. The FCU performs data conversion to the communication network and transmits it as facsimile data to the public line PN. Facsimile reception is performed by converting line data from the public line PN into image data by the FCU and transferring it to the IPP via the parallel bus Pb and CDIC. In this case, no special image quality processing is performed, and the image is output from the writing I / F 134 and a reproduced image is formed on the transfer paper in the image forming unit 135.
[0101]
In a situation where a plurality of jobs, for example, a copy function, a facsimile transmission / reception function, and a printer output function operate in parallel, the usage rights of the reading unit 211, the image forming unit 135, and the parallel bus Pb are allocated to the system controller 31a and the process. Control is performed by the controller 131. The process controller 131 controls the flow of image data, and the system controller 31a controls the entire system and manages the activation of each resource. The function selection of the digital multi-function peripheral is performed on the operation board 220, and processing contents such as an image reading function, an image data registration function, a copy function, a print function, a facsimile function, and a connection transfer function are selected by the selection input of the operation board 220. Set.
[0102]
The system controller 31a and the process controller 131 communicate with each other via the parallel bus Pb, CDIC, and serial bus Sb. Specifically, communication between the system controller 31a and the process controller 131 is performed by performing data format conversion for data and interface between the parallel bus Pb and the serial bus Sb in the CDIC.
[0103]
Various bus interfaces such as a parallel bus I / F 37, a serial bus I / F 39, a local bus I / F 33AA, and a network I / F 38 are connected to the IMAC. The system controller 31a is connected to related units via a plurality of types of buses in order to maintain independence in the entire ACP.
[0104]
The system controller 31a controls other functional units via the parallel bus Pb. The parallel bus Pb is used for transferring image data. The system controller 31a issues to the IMAC an operation control command for storing image data in the MEM and HDD. This operation control command is sent via IMAC, parallel bus I / F 37, and parallel bus Pb.
[0105]
In response to this operation control command, the image data is sent from the CDIC to the IMAC via the parallel bus Pb and the parallel bus I / F 37. The image data is stored in the MEM or HDD under the control of the IMAC.
[0106]
On the other hand, the ACP system controller 31a functions as a printer controller, network control, and serial bus control in the case of a call from the PC as a printer function. In the case of via the network, the IMAC receives print output request data via the network I / F 38.
[0107]
In the case of a general-purpose serial bus connection, the IMAC receives print output request data via the serial bus I / F 39. The general-purpose serial bus I / F 39 corresponds to a plurality of types of standards.
[0108]
Print output request data from the PC is developed into image data by the system controller 31a. The development destination is an area in MEM. Font data necessary for expansion is obtained by referring to the font ROM 36a via the local bus I / F 33a and the local bus Rb. The local bus Rb connects the controller 1 to the nonvolatile memory 35a and the RAM 34a.
[0109]
Regarding the serial bus Sb, in addition to the external serial port 32a for connection with the PC, there is also an interface for transfer with the operation board 220 which is an operation unit of the ACP. This is not print development data, but communicates with the system controller 31a via the IMAC, accepts processing procedures, displays the system status, and the like.
[0110]
Data transmission / reception between the system controller 31a and the MEM, HDD, and various buses is performed via the IMAC. Jobs that use MEM and HDD are centrally managed in the entire ACP.
[0111]
FIG. 6 shows an outline of the functional configuration of the CDIC. The image data input / output control 161 receives the image data output from the color document scanner 210 (SBU) and outputs it to the IPP. The IPP performs “scanner image processing” 190 (FIGS. 8 and 9) and sends it to the CDIC image data input control 162. The data received by the image data input control 162 is subjected to primary compression of the image data in the data compression unit 163 in order to increase the transfer efficiency on the parallel bus Pb. The compressed image data is converted into parallel data by the data converter 164 and sent to the parallel bus Pb via the parallel data I / F 165. Image data input from the parallel data bus Pb via the parallel data I / F 165 is serially converted by the data converter 164. This data is primarily compressed for bus transfer and is decompressed by the data decompression unit 166. The expanded image data is transferred to the IPP by the image data output control 167. In IPP, RGB image data is converted into YMCK image data by “image quality processing” 300 (FIGS. 8 and 9), and is converted into image data Yp, Mp, Cp, Kp for image output of the printer 100, and the color printer 100. Output to.
[0112]
The CDIC has a conversion function of parallel data transferred by the parallel bus Pb and serial data transferred by the serial bus Sb. The system controller 31a transfers data to the parallel bus Pb, and the process controller 131 transfers data to the serial bus Sb. For communication between the two controllers 1 and 131, the data conversion unit 164 and the serial data I / F 169 perform parallel / serial data conversion. The serial data I / F 168 is for IPP, and serial data transfer is performed with IPP.
[0113]
FIG. 7 shows an outline of the configuration of the IMAC. The IMAC includes an access control 172, a memory control 173, a secondary compression / decompression module 176, an image editing module 177, a system I / F 179, a local bus control 180, a parallel bus control 171, a serial port control 175, a serial port 174, and a network. A control 178 is provided. The secondary compression / decompression module 176, the image editing module 177, the parallel bus control 171, the serial port control 175, and the network control 178 are each connected to the access control 172 via a DMAC (direct memory access control).
[0114]
The system I / F 179 transmits / receives commands or data to / from the system controller 31a. Basically, the system controller 31a controls the entire ACP. The system controller 31a manages the resource allocation of the MEM and HDD, and controls other units through the system I / F 179, the parallel bus control 171 and the parallel bus Pb.
[0115]
Each unit of ACP is basically connected to the parallel bus Pb. Therefore, the parallel bus control 171 manages the transmission / reception of data to / from the system controller 31a, the MEM, and the HDD by controlling the bus occupation.
[0116]
The network control 178 controls connection with the LAN. The network control 178 manages transmission / reception of data to / from an external expansion device connected to the network. Here, the system controller 31a is not involved in the operation management of the connected devices on the network, but controls the interface in the IMAC.
[0117]
The serial port 174 connected to the serial bus has a plurality of ports. The serial port control 175 includes a number of port control mechanisms corresponding to the types of buses prepared. Separately from the external serial port, it controls the command reception with the operation unit or the transmission / reception of data related to display.
[0118]
The local bus control 180 interfaces with a local serial bus Rb to which a RAM 34a necessary for starting the system controller 31a, a nonvolatile memory 35a, and a font ROM 36a for expanding printer code data are connected.
[0119]
In the operation control, command control is performed by the system controller 31a from the system I / F 179. Data control manages MEM and HDD access from external units, with MEM and HDD as the center. Image data is transferred from the CDIC to the IMAC via the parallel bus Pb. Then, the image data is taken into the IMAC by the parallel bus control 171.
[0120]
Memory access of the captured image data leaves the management of the system controller 31a. That is, the memory access is performed by direct memory access control (DMAC) independently of the system control. For access to the MEM and HDD, the access control 172 arbitrates access requests from a plurality of units. The memory control 173 controls the access operation of the MEM and HDD or the data read / write.
[0121]
When accessing the MEM and HDD from the network, data taken into the IMAC from the network via the network control 178 is transferred to the MEM and HDD by the direct memory access control DMAC. The access control 172 arbitrates access to the MEM and HDD in a plurality of jobs. The memory control 173 reads / writes data to / from the MEM and HDD.
[0122]
When accessing the MEM and HDD from the serial bus, the data taken into the IMAC via the serial port 174 by the serial port control 175 is transferred to the MEM and HDD by the direct memory access control DMAC. The access control 172 arbitrates access to the MEM and HDD in a plurality of jobs. The memory control 173 reads / writes data to / from the MEM and HDD.
[0123]
Print output data from a PC connected to the network or serial bus is developed by the system controller 31a in the memory area in the MEM and HDD using the font data on the local bus.
[0124]
The system controller 31a manages the interface with each external unit. For data transfer after being taken into the IMAC, each DMAC shown in FIG. 7 manages memory access. In this case, since each DMAC performs data transfer independently of each other, the access control 172 gives priority to job collisions or access requests regarding access to the MEM and HDD.
[0125]
Here, the access to the MEM and the HDD includes an access from the system controller 31a via the system I / F 179 for developing a bitmap of stored data in addition to the access by each DMAC. The DMAC data permitted to access the MEM and HDD in the access control 172 or the data from the system I / F 179 is directly transferred to the MEM and HDD by the memory control 173.
[0126]
The IMAC has a secondary compression / decompression module 176 and an image editing module 177 for data processing therein. The secondary compression / decompression module 176 compresses and decompresses data so that image data or code data can be effectively stored in the MEM and HDD. The secondary compression / decompression module 176 controls the interface with the MEM and HDD by DMAC.
[0127]
The image data once stored in the MEM and HDD is called from the MEM and HDD to the secondary compression / decompression module 176 via the memory control 173 and the access control 172 by the direct memory access control DMAC. The image data thus converted is returned to the MEM and HDD by the direct memory access control DMAC or output to the external bus.
[0128]
The image editing module 177 controls the MEM and HDD by the DMAC, and performs data processing in the MEM and HDD. Specifically, the image editing module 177 performs rotation processing of image data, synthesis of different images, and the like as data processing in addition to clearing the memory area. The image editing module 177 reads the secondary compressed data from the MEM and HDD, decompresses the secondary compressed data to the primary compressed data by the secondary compression / decompression module 176, and uses the same decoding logic as the CDIC data decompression 163 in the module 177. The next compressed data is decompressed into image data, expanded in the memory in the module 177, and processed. The processed image data is subjected to primary compression with the same encoding logic as the CDIC primary compression logic, and further subjected to secondary compression with the secondary compression / decompression module 176, and written to the MEM and HDD.
[0129]
FIG. 8 shows an outline of IPP image processing. The read image is transmitted from the IPP input I / F (interface) to the “scanner image processing” 190 via the SBU and CDIC. This “scanner image processing” 190 is for the purpose of correcting the reading deterioration of the read image signal. After performing the shading correction, after performing the scanner gamma conversion, the data is transferred to the CDIC and stored in the MEM and HDD. Is called. Image data stored in the MEM and HDD and read out is transferred to the IPP again via the CDIC. Here, “background removal correction processing” is performed. Then, “image quality processing” 300 is performed.
[0130]
FIG. 9 shows an outline of the image processing function of IPP. IPP is separated and generated (determination of whether an image is a character area or a photographic area: image area separation) 192, background removal 193, scanner gamma conversion 194, filter 195, color correction 302, magnification change 303, image processing 304, printer gamma conversion 305 And gradation processing 606 is performed. IPP is a programmable arithmetic processing means for performing image processing. Image data input to the CDIC from the output I / F 12 of the scanner 210 is transferred to the IPP via the CDIC, and the signal deterioration accompanying the quantization to the optical system and the digital signal by the IPP (scanner signal deterioration). Is corrected and output (transmitted) to the CDIC again. In the IPP, “image quality processing” 300 is performed on the image data returned from the CDIC to the IPP. In “image quality processing” 300, RGB signals are converted into YMCK signals by color correction 302, and scaling processing such as scaling 303, image processing 304, printer gamma conversion 305, gradation conversion, dither processing, or error diffusion processing is performed. 306 etc. are performed.
[0131]
FIG. 10 shows an outline of the internal configuration of the IPP. The IPP accepts image data from the output I / F of the scanner 210 via the CDIC and inputs / outputs image data to / from the CDIC through the input / output port 141. Input / output image data is temporarily stored in a data buffer or input / output data register 142 including a bus switch and a buffer memory, and then input to the processor array 144 via the memory control of the SIMD type processor 143 or output to the CDIC. The Data for controlling IPP and image processing programs (programs and processing parameters) for IPP are stored in the HDD, and are given to the host buffer 147 by the transfer control of the system controller 31a, CDIC, or process controller 131, and stored in the data RAM 146 and program RAM 145. Written.
[0132]
In this embodiment, the processor array 144 is a group of single instruction stream multiple data stream (SIMD) processing elements (PE), and executes a single instruction in parallel for a plurality of data. PE (PE1, PE2, PE3,...) Processes each data. Each processing element PE (hereinafter also simply referred to as PE) includes an input / output register for storing data addressed to itself, a multiplexer (hereinafter referred to as MUX) for accessing a register of another PE, a logic An arithmetic unit (hereinafter referred to as ALU), an accumulator register (hereinafter simply referred to as an accumulator) for storing a logical result, and a temporary register for temporarily saving the contents of the accumulator.
[0133]
Each input / output register is connected to an address bus and a data bus (read line and word line), and stores an instruction code defining processing, data to be processed, and the like. The contents of the input / output register are input to the ALU, and the operation processing result is stored in the accumulator. To retrieve the result outside the PE, temporarily save it in a temporary register, write it to the input / output register (assigned to the output register), and output the result data of each PE sequentially (serially). Is obtained in raster (serial transfer) format.
[0134]
The instruction code is given to each PE with the same contents, different processing target data is given to each PE, and the contents of the input / output registers of adjacent PEs are referred to in the MUX, so that each PE is a process held by another PE. Calculations that have entered the target data can also be performed. The calculation result is output to the accumulator. All PEs simultaneously perform the same operation according to the same instruction code. That is, parallel processing is performed.
[0135]
For example, if the content of one line of image data is arranged in the PE for each pixel and is subjected to arithmetic processing with the same instruction code, a processing result for one line can be obtained in a shorter time than sequential processing for each pixel. Particularly, in the spatial filter processing, shading correction processing, and attribute detection processing, the instruction code for each PE is an arithmetic expression itself, and the processing can be performed in common for all the PEs.
[0136]
The input / output registers include a plurality of 8-bit registers each capable of inputting input data from the outside and further outputting to the outside. The ALU is a 16-bit ALU that can operate by loading data from the input / output register and can store the operation result in the input / output register. The accumulator and the temporary register also have a 16-bit configuration. Each ALU has a T register 1 bit, and the value of each ALU independently selects whether or not to execute the program processing.
[0137]
A plurality of PEs having the above configuration are arranged in parallel and operate in parallel according to a single program. In the following, a description will be given of data conversion in which image data of one pixel is converted by 1PE, and one block of image data on one raster is simultaneously gamma-converted. This gamma conversion is performed by the scanner gamma conversion 194 (FIG. 9) and the printer gamma conversion 305 (FIG. 9). In the scanner gamma conversion 194 and the printer gamma conversion 305, separate conversion characteristic defining data sets are used. These conversion characteristic defining data sets and the data conversion control program using them are registered in the HDD.
[0138]
When the document image is read by the scanner 210, a control program and reference data for the scanner image processing 190 including the scanner gamma conversion 194 are read from the HDD and written in the IPP program RAM 146 and the external data RAM 145. The global processor 149 performs scanner image processing 190 (FIG. 9) based on the data in the program RAM 146 and the external data RAM 145.
[0139]
When an image is printed out by the printer 100, a control program and reference data for the printer image quality processing 300 (FIG. 9) including the printer gamma conversion 305 are read from the HDD, and the IPP program RAM 146 (FIG. 10) and the external It is written in the data RAM 145. The global processor 148 performs printer image quality processing 300 based on the data in the program RAM 146 and the external data RAM 145.
[0140]
As shown in FIG. 11, in addition to the liquid crystal touch panel 79, the operation board 220 includes a numeric keypad 80a, a clear / stop key 80b, a start key 80c, an initial setting key 80d, a mode clear key 80e, and a test print key 80f. The test print key 80f is a key for printing only one copy regardless of the set number of print copies and confirming the print result. By pressing the initial setting key 80d, the initial state of the machine can be arbitrarily customized. The paper size stored in the machine can be set or the state set when the copy function reset key is pressed can be arbitrarily set. When the initial setting key 80d is operated, an “initial value setting” function for setting various initial values, an “ID setting” function, a “copyright registration / setting” function, an “usage record output” function, etc. A selection button to specify is displayed. Also, select applications that are preferentially selected when there is no operation for a certain period of time, set the transition time to low power according to the International Energy Star Plan, and set the transition time to auto-off / sleep mode. It is possible to set.
[0141]
On the liquid crystal touch panel 79, various function keys and a message indicating the state of the image forming apparatus are displayed. The liquid crystal display 79 includes a “copy” function, a “scanner” function, a “print” function, a “facsimile” function, an “store” function, an “edit” function, a “register” function, a “concatenate” function, and other functions. A function selection key 80g for selection and execution is displayed. An input / output screen determined for the function designated by the function selection key 80g is displayed. For example, when the “copy” function is designated, as shown in FIG. 11, the function keys 79a and 79b, the number of copies and the number of copies of the image forming apparatus are displayed. A message indicating the status is displayed. When the operator touches a key displayed on the liquid crystal touch panel 79, the key indicating the selected function is inverted in gray. When the details of the function must be specified (for example, the type of page printing), the detailed function setting screen is displayed by touching the key. Thus, since the liquid crystal touch panel uses a dot display device, it is possible to graphically perform an optimal display at that time. When the initial setting key 80d is pressed, the display on the liquid crystal touch panel 79 is switched to that shown in FIG.
[0142]
When the operation board 220 detects the operation of the initial setting key 80d, the operation board 220 displays the initial setting menu screen shown in FIG. When the “system initial setting” button on this menu screen is clicked, the operation board 220 displays the menu screen on the liquid crystal touch panel 79. When the user clicks the “link registration” button on the menu screen, the operation board 220 displays a link target device registration screen on the liquid crystal touch panel 79. When the user inputs a device name that can be an image data source (sending side) in the printing system shown in FIG. 1, the operation 220 board registers it in the image source table (one area of the memory) assigned to its internal non-volatile memory. To do. When the user inputs a device name that can be printed out, the operation 220 board registers it in the printer table (one area of the memory) allocated to the internal nonvolatile memory.
[0143]
When the “connection initial setting” button on the initial setting menu screen shown in FIG. 12 is clicked, the operation board 220 is displayed on the liquid crystal touch panel 79 and the printers and tables / tables registered in the printer table shown in FIG. An input screen for selecting the back side printing mode is displayed. Here, as shown in FIG. 13, when the user selects the front surface printing mode of the multi-function copying machine A and clicks “execute”, the operation board 220 transfers the input information to the system controller 31a, and the system controller 31a The process controller 131 is instructed to print out the designated front surface print mode or back surface print mode of the reference image AcP (FIG. 14) for automatic gradation calibration (Automatic Color Calibration) registered in the HDD. The reference image AcP is printed out. At this time, the reference image AcP, which is a color reference pattern, is written in the image forming units a, b, c, and d, transferred to the first transfer belt 7 after being developed, and when the front surface printing mode is designated. The image is transferred from the first transfer belt 7 to the sheet sent from the registration roller 33. When the reverse side printing mode is designated, the image is transferred from the first transfer belt 7 to the second transfer belt 13 as it is, and the second transfer belt 13 makes one round and is transferred to the paper.
[0144]
When this printing is completed, the system controller 31a displays the display on the liquid crystal touch panel 79 of the operation board 220 as a connected image source (image sending side), as shown in FIG. An input screen for selecting a reading mode is displayed. Here, as shown in FIG. 15, the user selects the front surface printing mode of the multi-function copier B, clicks “execute”, and the sheet on which the reference image AcP is printed is read by the scanner of the multi-function copier B. When the front side reading is set and the multi-function copying machine B is instructed to read the image and send it to the multi-function copying machine A, the multi-function copying machine B reads the reference image by the front side reading of the scanner, and the multi-function copying machine A Send image data to. Upon receipt of this, the ACP performs automatic gradation correction using the received image data (reference image AcP), and calculates adjustment data for high-quality printing in the surface printing mode of the multi-function copying machine A. In the HDD, it is registered as adjustment data for automatic gradation correction addressed to the connected printing mode, which is a combination of the surface reading mode of the multifunction copying machine B and the surface printing mode of the multifunction copying machine A. When this registration is completed, the ACP sends information indicating completion of setting of adjustment data for the combined printing of the surface image reading of the copying machine B and the surface printing of the copying machine A to the multi-function copying machine B that has sent the reference image data. Is sent with date data. The multi-function copier B registers the setting completion information of the adjustment data for the linked printing on the operation board (220) with the date data.
[0145]
Note that the reference image AcP shown in FIG. 14 has K patches Kp1, Kp2, and C (cyan) that represent K (black) continuously from the highest density to white (background), and C that represents C (cyan) continuously from the highest density to white (background). Patches Cp1, Cp2, M patches Mp1, Mp2 representing M (magenta) continuously from the highest density to white (background), and Y patches Yp1, Yp2 representing Y (yellow) continuously from the highest density to white (background) Are arranged at an equal pitch. Note that the paper on which the reference pattern is printed needs to be set on the contact glass (231) of the scanner (210) or the document table (241) of the ADF (230) in the correct direction. The mark is also printed. The user sets the printed reference image AcP on the contact glass (231) of the scanner (210) or the document table (241) of the ADF (230) in a predetermined direction according to the arrow mark.
[0146]
In this embodiment, the automatic gradation correction in the connected printing mode is performed by the gamma conversion 305 (FIG. 9), so that the image data of each color patch of the color reference image is sequentially given to the ACP IPP, The actual image data at the positions corresponding to the boundary density reference values 31, 63, 95, 127, 159, 191, and 223 that divide each color reference density range 0 to 255 into 8 on the color patch is used as the reference. Gamma conversion data for obtaining values is calculated and used as adjustment data. When the gamma conversion 305 using the adjustment data is executed, a control program and reference data (including adjustment data) for the printer image quality processing 300 (FIG. 9) including the printer gamma conversion 305 are read from the HDD and IPP. The program RAM 146 (FIG. 10) and the external data RAM 145 are written. In the gamma conversion 305, the global processor 148 converts the boundary density reference values 31, 63, 95, 127, 159, 191 and 223 of the respective color reference density ranges 0 to 255 based on the data in the program RAM 146 and the external data RAM 145. A gamma conversion table for each color reference density range 0 to 255 (entire range) is generated by interpolation based on the adjustment data addressed, and image data provided is corrected (gamma conversion) using the generated gamma conversion table.
[0147]
Although the copiers B and C have different mechanical structures, the electrical system configuration and functions are the same as those of the copier A described above. The printers D, E, and F have a configuration in which the scanner 210 and the ADF 230 of the electrical system shown in FIG. 5 are deleted, and the printing function and the external communication function are the same as those of the copier A. However, since there is no document reading function, the operation board 220 hides the “copy”, “scanner”, and “facsimile” buttons by masking. If a scanner and an ADF are added, these printers D, E, and F will have the same electrical system configuration and functions as the above-described copying machine A, even though they have different mechanical structures.
[0148]
The personal computer PC has hardware and application programs for realizing the functions corresponding to the functions of the image data processing apparatus ACP and the operation board shown in FIG. 5, and has no document reading function and printing function. There is a function for executing (commanding) each function shown in the block 80g.
[0149]
The document scanner G has a configuration in which the printer 100, the paper feed tray 270, and the paper feed bank 280 of the electrical system shown in FIG. 5 are deleted, and the image reading function and the external communication function are the same as those of the copying machine A. However, since there is no printing function, the operation board 220 hides the “copy”, “print”, and “facsimile” buttons by masking. When the number of printers 100 is increased, the document scanner also has the same electrical system configuration and function as the above-described copying machine A, although the mechanical structure is different.
[0150]
By executing the above-mentioned “connection initial setting” operation for each of the copying machines B and C and the document scanner G having the document scanner, the HDD of the copying machine A Each adjustment data for printing out the document read image data of the copying machines B and C and the document scanner G with the copying machine A with high image quality is registered. In the operation boards (220) of the copiers B and C and the document scanner G, the setting completion information of the adjustment data for the linked printing is registered with date data.
[0151]
Similarly, in the copying machine B, the copying machine A and C and the document scanner G are executed on the copying machines A and C and the document scanner G, respectively. Each adjustment data for printing out each original read image data with the copying machine B with high image quality is registered. In the operation boards (220) of the copying machines A and C and the original scanner G, the setting completion information of the adjustment data for the linked printing is registered with the date data.
[0152]
In the copier C, the original scanner of the copiers A and B and the original scanner G is read in the HDD of the copier C by executing each of the copiers A and B with the original scanner and the original scanner G. Each adjustment data for printing out the image data with the copying machine C with high image quality is registered. In the operation boards (220) of the copying machines A and B and the document scanner G, the setting completion information of the adjustment data for the linked printing is registered with date data.
[0153]
Also in each of the printers D, E, and F, the above-described “connection initial setting” operation is performed on each of the copiers A, B, and C and the document scanner G where the document scanner is provided, so that each printer D , E, F HDDs have adjustment data for printing out the original read image data of the copiers A, B, C, and the original scanner G with high image quality by the respective copier printers. Attached and registered. In the operation boards (220) of the copying machines A, B, C and the document scanner G, the setting completion information of the adjustment data for the linked printing is registered with date data.
[0154]
As described above, in this embodiment, the adjustment data for each link is registered in the HDD on the device side (A to C, D to F) that receives and prints out image data in the link, and is automatically used for link printing. The image quality adjustment is performed by the ACP (IPP) of the device that prints out.
[0155]
FIG. 11 will be referred to again. When the user clicks “link” among the function selection keys 80 g displayed on the liquid crystal touch panel 79, the operation board 220 displays a link printing input screen shown in FIG. 16 on the liquid crystal touch panel 79. The operation board 220 displays the device name registered in the image source table in the image source display block 80j of the input screen, and displays the device name registered in the printer table in the print display block 80k. Here, the user designates an image supply side device (usually his / her own device) by linked printing from the device name written in the image source display block 80j, and designates an image reading mode (front side reading and / or reverse side reading). To do. Then, from the device name written in the print display block 80k, specify the device (usually another device) that prints out by linked printing, specify the print mode (front side printing and / or back side printing), and specify the number of copies to print. To do. Then click “Execute”. In response to this, the operation board 220 notifies the input information to the ACP (system controller 31a), and controls the connection mode of image reading / image data transmission / image printing and image data transmission corresponding to the input information. .
[0156]
Note that, when specifying the linked printing, if the completion information of the adjustment data for the linked printing between the designated image source and the designated print output device is not registered, the operation board 220, as shown in FIG. Switch the corresponding printing device (D) in the printing device display block 80k of the liquid crystal touch panel 79 to the attention display, and point to it “There is no adjustment data for the connection. Please specify after initial setting of the connection. Then, the print quality will be worse.Do you want to continue? When the user clicks NO, the operation board 220 cancels the designation of the printing device (D). When the user clicks YES, the operation board 220 accepts the designation of the printing device (D), but since there is no adjustment data, the printing device (D) has standard adjustment data (normal copy or non-concatenation designation). Automatic gradation correction is performed using adjustment data (used in printing).
[0157]
Further, even if the adjustment completion setting information of the linked printing adjustment data is registered, if the date data attached thereto is older than the current date, the threshold period value set in the initial setting is older than the current date, the operation board 220 is displayed. As shown in FIG. 18, the corresponding printing device (E) in the printing device display block 80k of the liquid crystal touch panel 79 is switched to the attention display, and it indicates that “the adjustment data of the connection is too old. Specify after setting.The print quality may deteriorate.Do you want to continue? "NO, YES" alarm 80n pops up. When the user clicks NO, the operation board 220 cancels the designation of the printing device (E). When the user clicks YES, the operation board 220 accepts the designation of the printing device (E). In the printing apparatus (E), automatic gradation correction is performed using adjustment data that is considered to be old.
[0158]
In the embodiment described above, adjustment data for performing automatic gradation correction in linked printing is registered in the HDD on the printing device side, and the IPP on the printing device side uses the adjustment data to use the image reading side device. The automatic gradation correction is performed on the image data transmitted by the.
[0159]
In the second embodiment of the present invention, a reference image is printed on a sheet by a device (for example, B) that performs printing by linked printing. Then, the image on the image reading device (for example, A) reads the image on the sheet, and based on the read image data, the printing device (B) corrects the image to image data necessary for printing with high quality. The adjustment data is calculated and registered in the HDD of the reading device (A). When the combined printing of this combination is designated, the reading side device (A) is required to print the image data read by the original with the adjustment data using the adjustment data in the printing device (B) with high quality. The image data is corrected and transmitted to the printing device (B).
[0160]
In the first embodiment, the document reading side (each copying machine A, B, C and document scanner G) reads the document on the image printing side (each of the copying machines A, B, C and printers D, E, F). Each adjustment data for printing out the image data sent in high quality with its own printer is held, and the image printing side (each of the copiers A, B, C and printers D, E, F) makes each adjustment. Automatic gradation correction is performed based on the data. Therefore, in the first embodiment, each of the copiers A, B, and C and the printers D, E, and F, which are print members in the linked printing, is a copier A, B, C and an original scanner, which are image reading members in the linked print. Each adjustment data for correcting the image data of all G document scanners is held.
[0161]
However, in the second embodiment, the image reading side (each of the copying machines A, B, C and the printer D) receives the image data of the document reading on the image reading side (respectively of the copying machines A, B, C and the document scanner G). , E, F) holds adjustment data for correction to image data for high-quality printout, and the image reading side (each of copying machines A, B, C and document scanner G) sets each adjustment data. The automatic gradation correction is performed based on the image data, and the corrected image data is transmitted to the image printing side. Therefore, in the second embodiment, each of the copying machines A, B, and C and the document scanner G, which are image reading members in the linked printing, copies the image data generated by itself to the copying machines A and A that become the image printing members in the linked printing. Each adjustment data for correcting the image data to match the printing characteristics of B, C and printers D, E, F is held.
[0162]
【The invention's effect】
When image data is transferred from the document reading device of the image processing apparatus (B) to the image forming apparatus (A) and the adjustment data for the linked printing to be printed out by the image forming apparatus (A) is generated, the linked printing is designated. By simply doing, a high-quality printed image can be obtained. In other words, it is easy to set the connection mode for obtaining a high-quality print image.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an example of a printing system using an image processing apparatus of the present invention.
FIG. 2 is an enlarged front view showing an appearance of a full-color copying machine A having a composite image processing function shown in FIG.
3 is an enlarged vertical sectional view of the color printer 100 shown in FIG.
4 is an enlarged vertical sectional view of the color scanner 210 and the ADF 230 shown in FIG.
5 is a block diagram showing a configuration of an image processing system in the copying machine shown in FIG. 2. FIG.
6 is a block diagram showing a configuration of an image data interface control CDIC shown in FIG. 5. FIG.
7 is a block diagram showing a configuration of an image memory access control IMAC shown in FIG. 5. FIG.
8 is a block diagram showing an outline of processing functions of the image data processor IPP shown in FIG. 5. FIG.
9 is a block diagram showing the contents of the processing function shown in FIG.
10 is a block diagram showing an outline of a hardware configuration of the image data processor IPP shown in FIG. 5. FIG.
11 is an enlarged plan view of a part of the operation board 220 shown in FIG.
12 is a plan view showing a menu screen displayed on the liquid crystal touch panel 79 by the operation board 220 when an initial setting key 80d is operated. FIG.
13 is a plan view showing an input screen displayed on the operation board 220 when the user clicks a “connection initial setting” button shown in FIG. 12. FIG.
FIG. 14 is a plan view of a reference image AcP used for setting adjustment data for automatic gradation correction.
15 is a plan view showing an input screen displayed on the liquid crystal touch panel 79 by the operation board 220 following the print output of the reference image AcP. FIG.
16 is a plan view showing an input screen that is displayed on the liquid crystal touch panel 79 by the operation board 220 in response to the user clicking “connect” shown in FIG. 15 and designated and input by the user. FIG.
FIG. 17 is a plan view showing a warning displayed on the liquid crystal touch panel 79 by the operation board 220 when linked printing without adjustment data is designated.
FIG. 18 is a plan view showing a warning displayed on the liquid crystal touch panel 79 by the operation board 220 when linked printing with old adjustment data is designated.
[Explanation of symbols]
1: Photoconductor 2: Charging device
3: Developing device 4: Cleaning device
5: Static elimination device 6: Exposure device
7: First transfer belt
8-10: Roller
11: First transfer means
12: Cleaning device
13: Second transfer belt
14-16: Rotating roller
17: Second transfer means
18: Cleaning device
19: Charger
20: Paper (recording medium)
21, 22: Paper cassette
23: Fixing device 24: Paper discharge guide
25: Paper discharge roller
26: Output stack
27: Supply toner storage unit
28: Cartridge
29: Frame 30: Opening and closing spindle
31, 32: Paper feed roller
33: Registration roller
80j: Image source display block
80k: Print display block
80m, 80n: Alarm

Claims (6)

An image forming apparatus for printing an image represented by the image data on a recording medium;
Means for printing a reference image on a recording medium with the imaging device;
Communication means for receiving image data of a document reading device of a remote image processing device;
Based on the image data received by the communication means and read by the document reading device from the reference image recording medium, the image data of the document reading device is converted into image data for the image forming device to print with high image quality. Means for generating and storing adjustment data to be corrected; and
Image quality processing means for correcting the image data of the document reading apparatus received by the communication means using the adjustment data and providing the image forming apparatus;
An image processing apparatus comprising: An original document reading device that reads an image of the document; and means for designating transmission of image data of the document read by the document reading device; and the communication means performs image processing designated by the transmission designating means. The image processing apparatus according to claim 1, wherein the image data read by the original document reading apparatus is transmitted to the apparatus. A document reading device that reads an image of a document;
Based on the image data read by the original reading device of the reference image printed by the image forming device of the remote image processing device, the image forming device uses the image forming device to print the image data with high image quality. Means for generating and storing adjustment data for correction to image data;
Image quality processing means for correcting image data of document reading of the document reading device using the adjustment data;
Means for designating transmission of image data of a document read by the document reader; and
Communication means for transmitting the image data corrected by the image quality processing means to the image processing apparatus designated by the transmission designation means;
An image processing apparatus comprising: The means for generating the adjustment data includes a first surface and a second surface of the document reading apparatus that has read the reference image recording medium based on the image data read by the first surface and the second surface reading means. Generating each adjustment data for reading the first surface and the second surface for correcting each image data of the reading means into image data for the image forming device to print with high image quality;
The image quality processing means corrects each image data read by the first side and second side reading means of the document reading device using adjustment data for reading the first side and second side, respectively;
The image processing apparatus according to claim 1, 2 or 3. The image forming apparatus includes: an image forming unit that forms a visible image that represents an image represented by image data; a visible image holding unit that transfers a developed image formed by the image forming unit; and an image forming unit that is formed after the transfer. Means for transferring the developed image to one side of the recording medium and the developed image transferred to the image carrying means to the other side of the recording medium, image storage means for storing image data, and image storage In the case of double-sided printing based on the image data accumulated in the means, a first visible image is formed by the imaging means and transferred onto the transfer surface of the visible image carrying means, and after the first visible image, the A second visible image is formed by the image forming means, and the second visible image is transferred to one surface of the recording medium, and the first visible image transferred to the visible image holding means is transferred to the other surface of the recording medium. However, in the case of single-sided printing, a visible image is formed by the imaging means and transferred directly to the visible image holding means, and then recorded. Printing control means for transferring to a medium, printing of a reference image in a first transfer mode in which a visible image is formed by the imaging means and directly transferred to a recording medium, and a visible image is formed by the imaging means Means for printing a reference image on a recording medium, wherein the reference image is printed in a second transfer mode in which the image is transferred to the visible image carrying means and then transferred to a recording medium;
The means for generating the adjustment data is based on each image data read from the recording medium of the first transfer mode and the second transfer mode of the reference image. Generating respective adjustment data for the first and second transfer modes to be corrected to image data for printing with high image quality in the first and second transfer modes;
The image quality processing means uses the adjustment data for the first transfer mode when printing in the first transfer mode and the adjustment for the second transfer mode when printing in the second transfer mode. Correct using data;
The image processing apparatus according to claim 1. The means for designating transmission notifies a warning when transmission to an image processing apparatus that has not generated adjustment data for image data generated by the original document reading apparatus is designated; Image processing apparatus.

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