JP2004080319A - Image processing apparatus, image reading apparatus, and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processing apparatus that easily confirms whether or not set-off or erroneous image elimination by background elimination exists. <P>SOLUTION: The image processing apparatus includes: a low density image elimination means 45 that converts image information Din into first image information O, wherein image data satisfying a setting condition on the image and including low density image set-off and dirty background are corrected into image data denoting an image with the low density image deleted therefrom, and generates second image information (set-off binary image R, and set-off multi-value image Q) denoting a low density image area; and an image output means 20 for displaying the corrected image represented by the first image information O and the eliminated area image (set-off binary image R) denoted by the second image information, or an eliminated image (set-off multi-value image Q) on a screen 328 simultaneously or alternatively. An image reading apparatus and an image forming device are respectively provided with the image processing apparatus. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image processing apparatus having an image data correction function for automatically removing noise images, dirt images, background dirt, and the like, such as a show-through removal function or a background removal function, and an image reading apparatus and an image forming apparatus using the same. .
[0002]
[Prior art]
In order to reduce copy cost and print cost, there is a case where paper on which an image is already recorded on one of the front and back surfaces (back image paper) is reused as paper again, but the front image formed on the back image paper is copied. Occasionally, a copy of a front image with a back image is shown, which is called show-through. If there is no show-through image, but a document with show-through is copied, the copy will be as if the show-through has occurred.
[0003]
In order to eliminate such show-through, many show-through removal functions or background removal functions have been proposed. For example, in the image processing disclosed in Japanese Patent Application Laid-Open No. 2001-169080, a user sets a threshold for show-through removal in accordance with the degree of show-through and paper quality. The image forming control disclosed in Japanese Patent Application Laid-Open No. 2001-313832 selects a threshold for show-through removal according to the type of image.
[0004]
The present applicant has also disclosed the image data correction function in JP-A-2002-77607 and JP-A-2002-112033. Further, when the back image paper is used for copying or printing, for example, when the back image paper is fed when double-sided printing is designated, the back image becomes ugly. Therefore, in Japanese Patent Application Laid-Open No. 9-146420, a sensor for detecting whether a sheet is back image paper is provided in the copying machine, and an LCD panel (display editor) for image editing is provided in which cassette in the copying machine. Is displayed whether or not is stored.
[0005]
Conventionally, a show-through removal function that removes a back image from a show-through image obtained by reading a double-sided printed original and obtains only a front surface image, and a similar background / smear removal function that is similar to image data It is realized by a method of removing by processing and a mechanical method. An image forming apparatus having a display editor has a function of displaying a pre-scanned image on a display editor, performing processing by inputting a processing method on a display by a user, and outputting the processed image. There is.
[0006]
[Problems to be solved by the invention]
However, there is a problem that the image on the front surface is erroneously recognized as the image on the back surface (off-set image) or the background or the background stain and is removed by the image data processing of the show-through removal or the background removal.
[0007]
An object of the present invention is to make it easy to confirm whether there is an erroneous image removal.
[0008]
[Means for Solving the Problems]
(1) The image information (Din) is obtained by correcting image data of a low-density image (show-through, background stain) satisfying the setting conditions on the image represented by the image information (Din) into image data representing an image from which the low-density image has been deleted. Low-density image removing means (45) for converting into one image information (O) and generating second image information (R) indicating the low-density image area; and a corrected image represented by the first image information (O) And an image output means (20) for simultaneously or alternatively displaying the removal area image represented by the second image information (R) on the surface (328).
[0009]
In addition, in order to facilitate understanding, symbols or equivalents of corresponding elements or corresponding items of the embodiment shown in the drawings and described later are added for reference as examples in parentheses. The same applies to the following.
[0010]
According to this, the corrected image from which the low-density image (show-through, background stain) has been removed and the removed area image are displayed simultaneously or alternatively by the image output means (20). The user can visually confirm each image and confirm whether there is an erroneous image removal.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
(2) The first image information (O) and the second image information (R) are composed of data (multi-valued data, binary data) having different image representations; The image processing apparatus according to (1), wherein the corrected image (O) represented by the image information and the removal area image (S) represented by the second image information are synthesized (3 to 6 in FIG. 11);
[0012]
According to this, the corrected image (O) and the removal area are present on the composite image (T), and the user individually recognizes the correction image and the removal area by visual recognition, and incorrect image removal is performed on the corrected image (O). You can check if there is.
[0013]
(3) The image output means (20) converts the image information before conversion into the first image information, that is, the image represented by the original image information (Din) and the corrected image (O) represented by the first image information on the same plane. (FIG. 12); the image processing apparatus of (1) or (2) above.
[0014]
The user can check whether the corrected image (O) has an erroneous image removal by comparing the corrected image (O) with the original image displayed side by side by the image output means (20).
[0015]
(4) Multi-valued image data (Din) is multi-valued image data obtained by correcting image data of a low-density image that satisfies the setting conditions on the image represented by the corrected image data to image data representing an image from which the low-density image has been deleted. Low-density image removing means (45) for converting the image data into first image information (O) and generating second image information (Q) comprising multi-valued image data indicating only the low-density image; An image processing apparatus comprising: image output means (20: FIGS. 14 and 15) for displaying on a plane the removed image represented by (Q).
[0016]
The user visually checks the removed image represented by the image output means (20) and checks whether there is an image which should not be removed, and confirms whether the corrected image (O) has an incorrect image removal. be able to.
[0017]
(5) The image processing apparatus according to any one of (1) to (4); and a document scanner (10) which reads a document, generates image data, and supplies the image data to the low-density image removing means (45). An image reading device.
[0018]
According to this, in reading an original image, the operation and effect described in any of the above (1) to (4) can be obtained similarly.
[0019]
(6) The image processing device or the image reading device according to any one of (1) to (5); a printer (100) for forming an image represented by image data for recording on paper; and the first image An image forming apparatus comprising: an image data processing unit (ACP) that converts information (O) into image data for recording and supplies the converted image data to the printer (100).
[0020]
According to this, in the printing or copying of an image, the effects described in any of the above (1) to (5) can be similarly obtained.
[0021]
(7) The image output means (20) includes a display (79) for displaying an image on a surface, a display image selection means (318, 319) for a user to select and specify which image is to be displayed on the display, and Display mode selection means (320, 321) for the user to select and specify simultaneous output and alternative output of the image is included; (1) to (6) above.
[0022]
(8) In the image synthesis for simultaneous output of a plurality of images, the image output means (20) allows a user to select and designate an image characteristic (display color) of the removal area image represented by the second image information (R) to be synthesized. Means (325, 326); the above (1) to (7).
[0023]
(9) The image output means (20) sets a threshold (B, E, H) at which the low-density image removing means (45) determines that the low-density image (show-through, background stain) satisfies the setting condition. Includes input means (322 to 324) for changing; the above (1) to (8).
[0024]
(10) A show-through removal function (45) that removes show-through from a double-sided printed original to obtain only one-sided image information, and displays an image of the read original on a display editor (79) In an image forming apparatus having a function of performing
An image forming apparatus for displaying a result (corrected image) of performing a show-through correction on a read image on a display editor.
[0025]
The user can visually check the corrected image (O) on the display editor and determine whether the show-through correction is appropriate. After this display, the user adjusts the show-through correction as necessary, and instructs the print-out of the corrected image that the show-through correction is appropriate, thereby obtaining a print image assumed by the user. Can be.
[0026]
(11) In the image forming apparatus of the above (10), when a corrected image subjected to show-through correction is displayed on the display editor, a part of the image to be displayed which has undergone show-through correction is explicitly indicated to the user. (3 to 6 in FIG. 11).
[0027]
The user can recognize the removed show-through portion on the corrected image, and can easily determine whether the removed portion is appropriate. The operability for the user to make settings for show-through correction is improved.
[0028]
(12) In the image forming apparatus of (10), the original image before show-through correction and the corrected image subjected to show-through correction are displayed side by side on a display editor (FIG. 12).
[0029]
By displaying the original image before scanning and performing the show-through correction and the corrected image after performing the show-through correction side by side on the display editor, the correction result can be explicitly shown to the user. Improves the operability in setting the show-through correction.
[0030]
(13) In the image forming apparatus of the above (11), the image forming means that the original image before show-through correction and the image clearly showing the part subjected to show-through correction are displayed side by side on a display editor (FIG. 12). apparatus.
[0031]
By displaying the original image before scanning and performing show-through correction on the original and the corrected image showing the corrected portion after performing show-through correction on the display editor, the correction result is explicitly presented to the user. The operability is improved when the user makes settings for show-through correction.
[0032]
(14) In the image forming apparatus of (11) above, the corrected image after show-through correction and the show-through image (Q) removed by the correction are displayed side by side on a display editor (FIG. 15). apparatus.
[0033]
The image removed by the show-through correction can be explicitly shown to the user together with the corrected image, and the operability is improved when the user sets the show-through correction.
[0034]
Other objects and features of the present invention will become apparent from the following description of embodiments with reference to the drawings.
[0035]
【Example】
-1st Example-
FIG. 1 shows an appearance of a multifunction full-color digital copying machine according to a first embodiment of the present invention. The full-color copying machine generally includes units of an automatic document feeder (ADF) 30, an operation board 20, a color scanner 10, and a color printer 100. A finisher 34 with a tray capable of stacking staplers and formed images, a double-sided drive unit 33, an additional paper supply bank 35, and a large-capacity paper supply tray 36 are mounted on the printer 100. Peripheral units that can be separated from the printer 100, each having a control board having a power device driver, a sensor input, and a controller, and being directly connected to (the process controller 131 of FIG. 4) the control board of the printer 100 that is the main body of the image forming apparatus Alternatively, communication is performed indirectly and the paper is fed and conveyed under the timing control. The operation board 20 and the color scanner 10 with the ADF 30 are also units that can be separated from the printer 100, and the color scanner 10 also has a control board having a power device driver, a sensor input, and a controller. The document is read directly or indirectly and the timing is controlled to read the document image.
[0036]
A LAN (Local Area Network) to which a personal computer PC is connected is connected to the in-machine image data processing device ACP (FIG. 4), and a telephone line PN (facsimile communication line) is connected to the facsimile control unit FCU (FIG. 4). Is connected to the exchange PBX. The printed paper of the color printer 100 is discharged onto the paper discharge tray 108 or the finisher 34.
[0037]
FIG. 2 shows a mechanism of the color printer 100. The color printer 100 of this embodiment is a laser printer. In the laser printer 100, four sets of toner image forming units for forming images of each color of magenta (M), cyan (C), yellow (Y), and black (black: K) are arranged in a moving direction of the transfer paper. (From the lower right in the figure to the upper left y), they are arranged in this order. That is, it is a four-drum type full-color image forming apparatus.
[0038]
These magenta (M), cyan (C), yellow (Y), and black (K) toner image forming units include photoconductor units 110M, 110C, 110Y having photoconductor drums 111M, 111C, 111Y, and 111K, respectively. 110K and developing units 120M, 120C, 120Y and 120K. The arrangement of the toner image forming units is such that the rotation axes of the photosensitive drums 111M, 111C, 111Y and 111K in each photosensitive unit are parallel to the horizontal x-axis (main scanning direction), and the transfer paper It is set so as to be arranged at a predetermined pitch in the moving direction y (sub-scanning direction).
[0039]
In addition to the toner image forming unit, the laser printer 100 carries an optical writing unit 102 by laser scanning, paper feed cassettes 103 and 104, a pair of registration rollers 105, and a transfer paper. The image forming apparatus includes a transfer belt unit 106 having a transfer conveyance belt 160 that conveys the paper so as to pass through the transfer position, a fixing unit 107 of a belt fixing type, a paper discharge tray 108, a double-sided drive (surface inversion) unit 33, and the like. The laser printer 100 also includes a manual tray, a toner supply container, a waste toner bottle, and the like (not shown).
[0040]
The optical writing unit 102 includes a light source, a polygon mirror, an f-θ lens, a reflection mirror, and the like, and scatters a laser beam in the x direction on the surface of each of the photosensitive drums 111M, 111C, 111Y, and 111K based on image data. Irradiate while scanning. A dashed line in FIG. 2 indicates a transfer path of the transfer paper. The transfer paper fed from the paper feed cassettes 103 and 104 is conveyed by conveyance rollers while being guided by a conveyance guide (not shown), and is sent to the registration roller pair 105. The transfer paper sent to the transfer / conveyance belt 160 at a predetermined timing by the registration roller pair 105 is carried by the transfer / conveyance belt 160 and conveyed so as to pass through the transfer position of each toner image forming unit.
[0041]
The toner images formed on the photosensitive drums 111M, 111C, 111Y, and 111K of the respective toner image forming units are transferred to transfer paper carried and conveyed by the transfer / conveyance belt 160, and a superimposition of color toner images, that is, a color image is formed. The formed transfer paper is sent to the fixing unit 107. That is, the transfer is a direct transfer system in which a toner image is directly transferred onto a transfer sheet. When passing through the fixing unit 107, the toner image is fixed on the transfer paper. The transfer paper on which the toner image has been fixed is discharged or fed to the discharge tray 108, the finisher 36, or the double-sided drive unit 33.
[0042]
The outline of the yellow Y toner image forming unit will be described below. Other toner image forming units have the same configuration as that of yellow Y. The yellow Y toner image forming unit includes the photoconductor unit 110Y and the developing unit 120Y as described above. The photoconductor unit 110Y includes, in addition to the photoconductor drum 111Y, a brush roller that applies a lubricant to the surface of the photoconductor drum, a swingable blade that cleans the surface of the photoconductor drum, and a static elimination lamp that irradiates light to the surface of the photoconductor drum. And a non-contact type charging roller for uniformly charging the surface of the photosensitive drum.
[0043]
In the photoconductor unit 110Y, a laser beam modulated based on print data and deflected by a polygon mirror on the surface of the photoconductor drum 111Y uniformly charged by a charging roller to which an AC voltage is applied by an optical writing unit 102. When L is irradiated while being scanned, an electrostatic latent image is formed on the surface of the photosensitive drum 111Y. The electrostatic latent image on the photoconductor drum 11IY is developed by the developing unit 20Y to be a yellow Y toner image. At the transfer position where the transfer paper on the transfer conveyance belt 160 passes, the toner image on the photosensitive drum 11IY is transferred to the transfer paper. After the toner image is transferred, the surface of the photoreceptor drum 111Y is coated with a predetermined amount of lubricant by a brush roller, is cleaned by a blade, and is discharged by light emitted from a discharge lamp. It is provided for the formation of an electrostatic latent image.
[0044]
The developing unit 120Y contains a two-component developer containing a magnetic carrier and a negatively charged toner. The developing case 120Y includes a developing roller disposed so as to be partially exposed from the opening on the photosensitive drum side, a conveying screw, a doctor blade, a toner density sensor, a powder pump, and the like. The developer contained in the developing case is frictionally charged by being agitated and transported by the transport screw. Then, a part of the developer is carried on the surface of the developing roller. The doctor blade uniformly regulates the layer thickness of the developer on the surface of the developing roller, and the toner in the developer on the surface of the developing roller is transferred to the photosensitive drum, thereby forming a toner image corresponding to the electrostatic latent image on the photosensitive drum. Appears on drum 111Y. The toner density of the developer in the developing case is detected by a toner density sensor. When the density is insufficient, the powder pump is driven to supply toner.
[0045]
The transfer conveyance belt 160 of the transfer belt unit 106 is connected to four grounded stretching rollers so as to pass through respective transfer positions in contact with and facing the photosensitive drums 111M, 111C, 111Y and 111K of each toner image forming unit. It is hung around. One of the stretching rollers is 109. Of these tension rollers, an electrostatic attraction roller to which a predetermined voltage is applied is disposed so as to face an entrance roller on the upstream side in the transfer sheet moving direction indicated by a two-dot chain line arrow. The transfer paper that has passed between these two rollers is electrostatically attracted onto the transfer / conveying belt 160. The exit roller on the downstream side in the transfer paper moving direction is a drive roller that frictionally drives the transfer conveyance belt, and is connected to a drive source (not shown). In addition, a bias roller to which a predetermined cleaning voltage is applied from a power supply is arranged so as to come into contact with the outer peripheral surface of the transfer conveyance belt 160. The bias roller removes foreign matters such as toner adhered to the transfer / conveying belt 160.
[0046]
Further, a transfer bias applying member is provided so as to be in contact with the back surface of the transfer conveyance belt 160 forming a contact opposing portion that opposes the photoconductor drums 111M, 111C, 111Y and 111K. These transfer bias applying members are fixed brushes made of Mylar, and a transfer bias is applied from each transfer bias power supply. By the transfer bias applied by the transfer bias applying member, transfer charges are applied to the transfer / conveyance belt 160, and a transfer electric field having a predetermined intensity is formed between the transfer / conveyance belt 160 and the surface of the photosensitive drum at each transfer position. .
[0047]
The sheet on which the toner images of the respective colors formed on the photosensitive drums 111M, 111C, 111Y, and 111K are transferred by the transfer and transfer belt 160 is sent to the fixing device 107, where the toner image is heated and pressed to form a sheet. Is heat-fixed. After the heat fixing, the sheet is sent to the finisher 34 from a discharge port 34ot to the finisher 34 on the upper portion of the left side plate. Alternatively, the paper is discharged to a paper discharge tray 108 on the upper surface of the printer body.
[0048]
Of the four photosensitive drums, the photosensitive drums 111M, 111C, and 111Y for forming a magenta image, a cyan image, and a yellow image are one electric motor (color drum motor; color drum motor) for driving a color drum (not shown). M: not shown), and is driven at a one-step speed reduction via a power transmission system and a speed reducer (not shown). The photosensitive drum 111K for forming a black image is driven by a single electric motor (K drum motor: not shown) for driving the black drum at a one-step speed reduction via a power transmission system and a speed reducer (not shown). You. The transfer conveyance belt 160 is rotated by driving a transfer drive roller via a power transmission system by the K drum motor. Accordingly, the K drum motor drives the K photoconductor drum 11K and the transfer / transport belt 60, and the color drum motor drives the M, C, Y photoconductor drums 11M, 11C, 11Y.
[0049]
The K developing device 120K is driven by an electric motor (not shown) driving the fixing unit 107 via a power transmission system and a clutch (not shown). The M, C, Y developing units 120M, 120C, 120Y are electric motors (not shown) for driving the registration rollers 105, and are driven via a power transmission system and a clutch (not shown). The developing units 120M, 120C, 120Y, 120K are not always driven, but receive drive transmission by the clutch so that they can be driven at a predetermined timing.
[0050]
FIG. 1 is referred to again. The finisher 34 has a stacker tray, that is, a stacking and lowering tray 34hs and a sort tray group 34st. It has a sorter discharge mode.
[0051]
The paper fed from the printer 100 to the finisher 34 is conveyed in the upper left direction, passes through an inverted U-shaped conveyance path, switches the conveyance direction downward, and then discharges the paper in the stacker according to the set mode. In the mode, the sheet is discharged from the discharge port to the loading and lowering tray 34hs. In the sorter discharge mode, the sheet currently discharged in the sorter tray group 34st is discharged to the assigned sorter tray.
[0052]
When the sorter discharge mode is designated, the discharge controller in the finisher drives the sort tray group 34st placed at the lowermost stacking and retract position to the use position indicated by the two-dot chain line in FIG. Increase the interval. In the sorter discharge mode, a single (one) copy or print of the set number of sheets is performed. When the sorter discharge mode is set for the set sort, each transfer sheet on which the same original (image) is printed is sorted by the sort tray group 34st. Sorted and stored in each tray. When the sorter discharge mode is set for page sorting, each tray is assigned to each page (image), and each transfer sheet on which the same page is printed is stacked on one sort tray.
[0053]
FIG. 3 shows a document image reading mechanism of the scanner 10 and the ADF 30 attached thereto. The original placed on the contact glass 231 of the scanner 10 is illuminated by the illumination lamp 232, and the reflected light (image light) of the original 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) driven at a constant speed in the sub-scanning direction y. The second carriage (not shown), which is driven at the half speed in the same direction as the first carriage, has the second and third mirrors 234 and 235 mounted thereon, and the image light reflected by the first mirror 233 is The light is reflected by the second mirror 234 in the downward direction (z), is reflected by the third mirror 235 in the sub-scanning direction y, is converged by the lens 236, is irradiated on the CCD 207, and is converted into an electric signal. The first and second carriages are driven forward (scanning original) and backward (return) in the y direction by the driving motor 238 as a driving source.
[0054]
The scanner 10 is equipped with an automatic document feeder ADF 30. The document stacked on the document tray 241 of the ADF 30 is sent between the conveyance drum 244 and the pressing roller 245 by the pickup roller 242 and the registration roller pair 243, and passes over the reading glass 240 in close contact with the conveyance drum 244. Then, the paper is discharged onto the paper discharge tray 248 below the original tray 241 by the paper discharge rollers 246 and 247. When the document passes through the reading glass 240, the document is illuminated by the illumination lamp 232 moving immediately below the document. The reflected light of the document is radiated to the CCD 207 via the optical system below the first mirror 233 and photoelectrically converted. You.
[0055]
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 start of the document. The white reference plate 239 reads the original with a uniform density due to variations in the individual light emission intensities of the illumination lamps 232, variations in the main scanning direction, and unevenness in sensitivity of each pixel of the CCD 207. It is provided for correcting a phenomenon in which the read data varies (shading correction). In this shading correction, first, the white reference plate 239 is read for one line in the main scanning direction before scanning the document, the read white reference data is stored in a memory, and when reading a document image, The image data is divided by the corresponding white reference data in the memory.
[0056]
FIG. 4 shows a system configuration of an image processing system of the copying machine shown in FIG. In this system, a color document scanner 10 including a reading unit 11 and an image data output interface (I / F) 12 is connected to an image data interface control CDIC (hereinafter simply referred to as CDIC) of an image data processing device ACP. I have. A color printer 100 is also connected to the image data processing device ACP. The color printer 100 receives recording image data from the image data processor IPP (Image Processing Processor; hereinafter simply referred to as IPP) of the image data processing device ACP to the writing I / F 134, and prints out the image at the image forming unit 135. . The image forming unit 135 is as shown in FIG.
[0057]
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 & hard disk; hereinafter simply referred to as MEM), The system includes a system controller 1, a RAM 4, a nonvolatile memory 5, a font ROM 6, a CDIC, an IPP, and the like. The facsimile control unit FCU (hereinafter simply referred to as FCU) is connected to the parallel bus Pb. The operation board 20 is connected to the system controller 1.
[0058]
The reading unit 11 of the color document scanner 10 for optically reading a document generates a R, G, B image data by photoelectrically converting the reflected light of the lamp irradiation on the document by a CCD on the sensor board unit SBU to generate RGB image data. The data is converted to data and subjected to shading correction, and sent to the CDIC via the output I / F 12.
[0059]
The CDIC performs image data transfer between the output I / F 12, the parallel bus Pb, and the IPP, and communication between the process controller 131 and the system controller 1 that controls the entire ACP. The RAM 132 is used as a work area of the process controller 131, and the nonvolatile memory 133 stores an operation program of the process controller 131 and the like.
[0060]
The MEM also has a hard disk for storing a large amount of image data in addition to the semiconductor memory. By using a hard disk, there is also a feature that an external power supply is unnecessary and an image can be held permanently. It can read many document images by a scanner and hold them on a hard disk, and can hold many document images given by a PC.
[0061]
The image memory access control IMAC (hereinafter simply referred to as IMAC) controls writing / reading of image data to / from the MEM. The system controller 1 controls the operation of each component connected to the parallel bus Pb. The RAM 4 is used as a work area of the system controller 1, and the nonvolatile memory 5 stores an operation program of the system controller 1 and the like.
[0062]
The operation board 20 inputs a process to be performed by the ACP. For example, the type of process (copying, facsimile transmission, image reading, printing, etc.), the number of processes, and the like are input. Thereby, the input of the image data control information can be performed.
[0063]
Image data read by the reading unit 11 of the scanner 10 is subjected to shading correction by an SBU (sensor board unit) of the scanner 10, and then subjected to image processing for correcting reading distortion such as scanner gamma correction and filter processing by IPP. And then accumulate in MEM. When printing out MEM image data, the IPP performs color conversion of RGB signals into 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 write I / F 134. The write I / F 134 performs laser control on the signal subjected to the gradation processing 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 transfer paper.
[0064]
The IMAC is for controlling access to image data and MEM based on the control of the system controller 1, developing print data for a personal computer PC (hereinafter simply referred to as PC) connected to the LAN, and effectively utilizing the MEM. Compression / expansion of the image data.
[0065]
The image data sent to the IMAC is stored in the MEM after data compression, and the stored image data is read as needed. The read image data is expanded, returned to the original image data, and returned from the IMAC to the CDIC via the parallel bus Pb. After the transfer from the CDIC to the IPP, the image is processed and output to the write I / F 134, and the image forming unit 135 forms a reproduced image on transfer paper.
[0066]
In the flow of image data, the function of the digital multifunction peripheral is realized by the bus control by the parallel bus Pb and the CDIC. The facsimile transmission is performed by performing image processing on image data read by the scanner 10 by IPP and transferring the image data to the FCU via the CDIC and the parallel bus Pb. The FCU converts the data into a communication network and transmits it to the public line PN as facsimile data. 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, the image is output from the writing I / F 134 without performing any special image quality processing, and the image forming unit 135 forms a reproduced image on transfer paper.
[0067]
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 right to use the reading unit 11, the imaging unit 135, and the parallel bus Pb is assigned to the job by the system controller 1 and the process. Control is performed by the controller 131. The process controller 131 controls the flow of image data, the system controller 1 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 20, and the processing contents such as the copy function and the facsimile function are set by the selection input of the operation board 20.
[0068]
The system controller 1 and the process controller 131 communicate with each other via the parallel bus Pb, the CDIC, and the serial bus Sb. Specifically, communication between the system controller 1 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.
[0069]
Various bus interfaces, for example, a parallel bus I / F 7, a serial bus I / F 9, a local bus I / F 3, and a network I / F 8, are connected to the IMAC. The controller unit 1 is connected to related units via a plurality of types of buses in order to maintain independence in the entire ACP.
[0070]
The system controller 1 controls other functional units via the parallel bus Pb. The parallel bus Pb is used for transferring image data. The system controller 1 issues an operation control command to the IMAC to store the image data in the MEM. This operation control command is transmitted from the IMAC and the parallel bus I / F.
7. Sent via the parallel bus Pb.
[0071]
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 / F7. Then, the image data is stored in the MEM under the control of the IMAC.
[0072]
On the other hand, the system controller 1 of the ACP functions as a printer controller, a network controller, and a serial bus controller in the case of calling from a PC as a printer function. In case of network connection, IMAC is network I / F
8, print output request data is received.
[0073]
In the case of a general-purpose serial bus connection, the IMAC receives print output request data via the serial bus I / F 9. The general-purpose serial bus I / F 9 supports a plurality of types of standards, for example, an interface of a standard such as USB (Universal Serial Bus), 1284, or 1394.
[0074]
Print output request data from the PC is developed into image data by the system controller 1. The deployment destination is an area in the MEM. Font data necessary for development can be obtained by referring to the font ROM 6 via the local bus I / F 3 and the local bus Rb. The local bus Rb connects the controller 1 to the nonvolatile memory 5 and the RAM 4.
[0075]
As for the serial bus Sb, besides the external serial port 2 for connection with the PC, there is also an interface for transfer with the operation board 20 which is the operation unit of the ACP. It communicates with the system controller 1 via IMAC instead of print development data, accepts processing procedures, displays system status, and the like.
[0076]
Data transmission / reception between the system controller 1 and the MEM and various buses is performed via the IMAC. Jobs using MEM are centrally managed in the entire ACP.
[0077]
As shown in FIG. 5, the operation board 20 includes a liquid crystal touch panel 79, a numeric keypad 80a, a clear / stop key 60b, a start key 60c, a mode clear key 60e, a test print key 80f, a "copy" function, and a "scanner". There is a function selection key 80g for selecting a function, a "print" function, a "facsimile" function, a "storage" function, an "edit" function, a "registration" function and other functions and indicating that the function is being executed.
[0078]
The main part of the electric control system of the operation board 20 communicates with the system controller 1, reads an input of the operation board 20, controls a display on the board, a ROM in which a control program of the CPU is stored, For temporarily storing data, a VRAM for storing drawing data of the liquid crystal touch panel 79, a liquid crystal display controller (LCDC) connected to the VRAM for controlling drawing timing of the liquid crystal touch panel 79, and a clock IC for generating time data Etc. The CPU of the operation board 20 is connected to a key matrix of an operation key group, an LED matrix of display LEDs, an LED driving device for driving the LEDs, and the like. Further, a nonvolatile RAM (NVRAM) is connected to a data bus to which the CPU of the operation board 20 is connected.
[0079]
On the liquid crystal touch panel 79, an input / output screen determined by the function specified by the function selection key 80g is displayed. For example, when the "copy" function is specified, the function keys 79a and 79b, and the "show-through removal setting" key 311 and the like, and a message indicating the number of copies and the state of the image forming apparatus are displayed. The test print key 80f is a key for printing only one copy regardless of the set number of prints and confirming a print result.
[0080]
The “character” designation key 80h is selected and operated when the user recognizes that the image is a binary image such as a sentence or a line drawing, and the “dot” designation key 80i is a halftone or gray expression such as a dot or a photograph or a painting. Selection operation is performed when it is recognized that When there is a "character" designation, the data (1 bit signal) representing these designations is at a high level "1", and when there is a "dot" designation, it is at a low level "0". When “character” is specified, the IPP performs processing for clearly expressing characters and lines on the image data, and when “dot” is specified, the IPP performs processing for smoothly displaying a gradation image such as a photograph.
[0081]
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, and a "use record output" function are provided. Is displayed. In the “initial value setting”, it is determined whether or not the smoothing 71 is to be added to the image data L that has undergone density conversion for show-through removal 45 shown in FIG. There is a setting of "automatic / selection" for setting whether to select automatically or to select according to the user's "character" designation key 80h or "dot" designation key 80i, that is, according to the user's selection. (1 bit signal) is high level “1” when “automatic” is set, and low level “0” when “select” is set.
[0082]
In FIG. 6, when the copy instruction input standby screen (FIG. 5) is displayed on the liquid crystal touch panel 79, the user touches the “show-through removal setting” key 311 on the screen with a finger or an input pen. 9 shows an input screen for “show-through removal setting” displayed on the liquid crystal touch panel 79 by the operation board 20.
[0083]
A task bar image having keys 312 to 316 for instructing the progress of the show-through removal input and a document page display 317 is provided on the upper side of the liquid crystal touch panel 79. The "Previous" key 312 is a display screen return instruction key, and when the user touches the key, the operation board 20 returns the display of the liquid crystal touch panel 79 to the copy instruction input standby screen (FIG. 5). An "OK" key 313 is a key (corrected image print start key) for instructing a print output of a corrected image of a document displayed on the liquid crystal touch panel 79 as a page (317) with show-through removed. The “release show-through removal” key 314 is used to designate the print output of the document displayed on the page as an original image without show-through removal. When the user touches this, the operation board 20 displays the image display area 328. When the "OK" key 313 is touched, the operation board 20 interprets it as a print output instruction of the original image. A “next page” key 315 is used to scan the original page of the show-through elimination setting when the scanner 10 successively reads the originals of a plurality of pages in the ADF 30 next to the page currently displayed on the page display 317. A "previous page" key 316 is a key for instructing switching to a page, and is a key for instructing switching to the previous page.
[0084]
On the right side of the liquid crystal touch panel 79, there is a display condition input screen, in which display windows 319, 321, 324, and 326 for selecting a display image, a display mode, adjusting a show-through threshold, and selecting a show-through part display color. In addition, there are selection update keys 318, 320, 325, up-down keys 322, 323 and a determination instruction key 327. In the mode for displaying an image in the image display area 328, in addition to the default (set to standard) “after removal image only”, “source & after removal image” (display of original image and corrected image side by side), “ "Original image only", "Show-through image only" (display of removed show-through image (multi-valued)) and "Removed &show-through" (display of corrected image and removed show-through image (multi-valued) side by side) There is. On the initial screen of the show-through removal setting, the default “only the image after removal” is displayed on the display window 319. However, when the user touches the selection update key 318 once, the display window 319 displays “Original & After Removal”. "Image" is displayed. When the touch is further repeated, the display of the display window 319 is sequentially switched to “only the original image”, “only the show-through image”, and “after removal and show-through”, and the default after “after removal and show-through” is displayed. To “Only the image after removal”. The key 318 is a scroll key.
[0085]
The display of the original image and the post-removal image (corrected image) are respectively performed in the “as-image” mode in which the image is displayed as it is, and in the “removed image and the back One of the modes of “identify a captured image” can be selected. This is "display mode selection". Then, the image characteristics are selected so that the show-through image can be identified. In this embodiment, this is the selection of the “show-through part display color”. The default of the “display mode selection” is the mode of “identify the after-removed image and the show-through image” displayed in the display window 321, but the mode is switched to the “as image” mode by touching the scroll key 320. Can be.
[0086]
The default of the “show-through part display color” is “gray” displayed in the display window 326, but can be switched to black, blue, red or yellow by touching the scroll key 325.
[0087]
In the initial display, the default values of the show-through cutout thresholds B, E, and H are displayed on the display window 324. However, the user touches the selection button 328 to specify the threshold to be changed, and the up-down key 322 , 323, the values of the thresholds B, E, H can be individually increased or decreased.
[0088]
When the user touches the “OK” key 327, the operation board 20 sets the information currently displayed on the windows 319, 321, 324, and 326 as the show-through removal condition of the document on the display page (317).
[0089]
Vertical and horizontal scroll bars are displayed in the image display area 328. By touching and sliding these, an image portion displayed in the area 328 can be scrolled. As a result, an image having a size larger than the display size of the liquid crystal touch panel 79 can be displayed in the area 328.
[0090]
FIG. 7 shows an outline of the image processing function of the IPP. The read image data provided by the scanner 10 via the CDIC is transmitted from the SBU via the CDIC from the input I / F (interface) 41 of the IPP to the scanner image processing 42. The scanner image processing 42 performs scanner γ correction, MTF correction, and the like with the main purpose of correcting image information deterioration due to reading. Although not a correction process, a scaling process for enlargement / reduction is also performed. After the correction processing of the read image data is completed, the image data is transferred to the CDIC via the output I / F 43. For output to transfer paper, image data from the CDIC is received from the input I / F 44, and area gradation processing is performed in the image quality processing 46. The data after the image quality processing is output to the write I / F 134 via the output I / F 47. The area gradation processing includes density conversion, dither processing, error diffusion processing, and the like, and the main processing is area approximation of gradation information.
[0091]
Once the image data subjected to the scanner image processing 42 is stored in the memory MEM, various reproduced images can be confirmed by changing the processing performed in the image quality processing 46. For example, by changing the density of the reproduced image or changing the number of lines of the dither matrix, the atmosphere of the reproduced image can be changed. At this time, it is not necessary to read the image again by the scanner 10 every time the processing is changed, and by reading the stored image from the MEM, different processing can be performed on the same data as many times as necessary.
[0092]
When the user touches the “show-through removal setting” key 311 while the screen of the copy input mode shown in FIG. 5 is displayed on the liquid crystal touch panel 79, the operation board 20 displays “show-through removal” shown in FIG. Display the default screen of "Setting" (standard screen: initial screen). After the display is switched in this way, if the user inputs (touches) on the display condition input screen on the right side of the liquid crystal touch panel 79, the display condition input screen is changed in response to the user's input (touch). When the "OK" key 327 on the display condition input screen is touched, the data in the show-through removal condition register (one area of the internal memory of the operation board) is updated to the information displayed on the display condition input screen at that time. .
[0093]
When the copy start key (80c) is operated while the “show-through removal setting” screen (FIG. 6) is displayed, the operation board 20 adds the information of the show-through removal condition register to the scanner image. A read command is given to the system controller 1. The system controller 1 sets the writing of the scanner read image data to the MEM in the CDIC and the IMAC, and gives an image reading command to the scanner 10 via the process controller 131.
[0094]
In response to this, if there is a document on the ADF 30, the scanner 10 starts reading the document, converts the image of the document into image data, performs shading correction, and outputs the image data to the IPP via the CDIC. The scanner 10 sequentially performs this image reading on all the originals in the ADF 30 and notifies the system controller 1 via the process controller 131 when the reading of all the originals is completed. If there is no original in the ADF 30, the scanner 10 starts scanning the original image on the contact glass by scanning and driving the carriage, and notifies the end when the reading is completed.
[0095]
The CDIC sends image data generated by the scanner 10 to the IPP, sets data transfer to send the image data processed by the IPP to the parallel bus Pb, and the IMAC writes the image data sent to the parallel bus Pb to the MEM. Transfer data. The IPP processes the image data generated by the scanner 10 in the scanner image processing 42 and outputs the processed data to the CDIC. The CDIC performs primary compression to increase the data transfer efficiency and sends the data to the parallel bus Pb. The primary compressed data sent to the parallel bus Pb is subjected to secondary compression for increasing the memory storage efficiency, and is written to the MEM.
[0096]
When the scanner 10 finishes reading the image and the read image data is written to the MEM, the system controller 1 performs the show-through removal processing on the image data written to the MEM to the IMAC, CDIC, and IPP, and executes the resulting image. Data processing for writing data (O, Q, R) into the MEM is set. In response to this, the IMAC reads the written image data (first page if there are a plurality of pages) from the MEM and gives it to the IPP, and performs the IPP show-through removal 45 to remove the show-through. After (corrected image) data (O: FIG. 8), show-through multi-valued image data (Q: FIG. 8) representing the removed image and show-through binary image data (R: FIG. 8) representing the removed image are generated. Then, these three types of image data (three sets of images) are output to the CDIC, the CDIC performs a primary compression on them, and the IMAC performs a secondary compression on the compressed data and writes it to the MEM. When a document image of a plurality of pages is written in the MEM, the above-described three sets of image data (O, Q, R) are generated and written in the MEM for the document of each page.
[0097]
FIG. 8 shows a functional configuration of the “show-through removal processing” 45 of the IPP. In the density difference detection matrix 61 of the flatness detection 60, the image data of each pixel of the 3 × 3 pixel matrix centered on the target pixel (density value e) to which the currently supplied image data Din is addressed is written. Assuming that the density values represented by these image data are a to i as shown in FIG. 9A, the flatness detection 60 determines the density difference A () in the pixel matrix 61 shown in FIG. A1 to A8) are calculated, and it is checked by the comparator 62 (comparison) whether any of these is less than the flat detection threshold value B which is the set low density value, and the density difference A (all of A1 to A8) is calculated. ) Is less than the threshold B, the flat detection signal C is set to a high level 1 indicating flatness, and if any of A1 to A8 is equal to or more than the threshold B, the flat detection signal C is cleared to a low level 0 indicating non-flatness. . This flat detection signal C is used as one input of a logical product operation 69. When there is a halftone dot in the image data, the density difference A becomes equal to or less than the threshold value B.
[0098]
In the density detection 63, the comparator 64 checks whether the density value e = D of the pixel of interest is less than the threshold E for low density detection, and if it is less than the threshold E, the low density detection signal F is converted to a low density. The level is set to a high level 1 indicating that there is a certain level. This low concentration detection signal F is also one input of the logical product operation 69.
[0099]
The halftone dot detection 65 calculates an average value of the image data of the target pixel and the seven pixels before and after the target pixel, that is, a total of eight pixels, by an averaging operation 66. This is derived by multiplying each of the eight pixel image data by the same coefficient 1 shown in FIG. 10A to reduce the product to 1/8 (throw out the lower 3 bits). This is equivalent to one-dimensional smoothing filter processing with equal weighting.
[0100]
In the halftone dot detection 65, the comparator 68 compares the difference value G obtained by subtracting the average value from the density value represented by the image data of the target pixel with the threshold value H for halftone dot detection, and determines that the difference value G is less than the threshold value H. When the difference value G is equal to or more than the threshold value H, the non-halftone dot detection signal I is set to a low level 0 indicating that it is a halftone dot. clear. This non-dot detection signal I is also one input of the AND operation 69.
[0101]
The output J of the AND operation 69 becomes high level 1 when all three of the flat detection signal C, the low density detection signal F, and the non-dot detection signal I are 1. That is, when the image density distribution is flat, the image density of the pixel of interest is low, and it is not a halftone dot portion, and it can be regarded as show-through, the output J of the logical product operation 69 becomes high level 1 representing show-through.
[0102]
The image data of the target pixel is given to the density converter 70, and when the output J of the logical product operation 69 is at the high level 1 representing show-through, the density converter 70 converts the image data of the target pixel into the set low level equivalent to the background level. Change to K and output (L). When the output J of the AND operation 69 is at the low level 0 (non-show-through), the density converter 70 outputs (L) the image data of the target pixel as it is.
[0103]
The image data L output from the density converter 70 is supplied to a smoothing 71 and an output selector 72. The smoothing 71 performs a smoothing filter process on the image data L using the filter coefficients shown in FIG. In the pixel matrix distribution of the filter coefficient shown in FIG. 10B, a high weight is given to the target pixel, the next highest weight is given to the nearest pixel whose side is in contact with the pixel, and a low weight is given to the neighboring pixel which is in contact with the corner. Is to give. Therefore, the smoothing 71 is a calculation of the weighted average value of the image data of the small area centering on the target pixel, and the density level of the peripheral pixel is reflected on the target pixel density level (M).
[0104]
The output I of the halftone dot detection 65 is also given to the smoothing selection 73. The smoothing selection 73 is also supplied with an automatic / selection signal indicating whether automatic designation or selection designation set on the operation board 20, and a character / halftone signal representing character designation or halftone designation. The high level 1 of the 1-bit automatic / selection signal indicates that "automatic" is designated, and the low level 0 indicates that "selection" is designated. The high level 1 of the 1-bit character / dot signal indicates that "character" is specified, and the low level 0 indicates that "dot" is specified.
[0105]
When the automatic / selection signal is at the high level 1 designating "automatic", the AND gate 74 is gate-on, the AND gate 75 is gate-off, and the non-dot detection signal I of the dot detection 65 is passed through the OR gate 76 to the selector 72. The selector 72 sets the smoothed image data M as the output O of the show-through removal processing 45 when the non-halftone dot detection signal I is at the high level 1 indicating a non-halftone dot. When I is a low level 0 indicating a halftone dot, image data L = N that is not smoothed is set as an output O of the show-through removal processing 45.
[0106]
When the automatic / selection signal is at the low level 0 designating "selection", the AND gate 74 is gate-off, the AND gate 75 is gate-on, and the character / dot signal is supplied to the selector 72 through the AND gate 75 and the OR gate 76. The selector 72 sets the smoothed image data M as the output O of the show-through removal processing 45 when the character / halftone signal is at the high level 1 indicating “character”. The image data L = N that is not smoothed when the level is “0” at the low level indicating “point” is set as the output O of the show-through removal processing 45.
[0107]
By the above processing, when a halftone dot is not detected by the halftone dot detection 65, density conversion is performed based on the detection results of the flatness detection 60 and the density detection 63, and show-through is removed.
[0108]
By performing the smoothing 71 on the output L of the density conversion 70, the density discontinuities after the density conversion are averaged and become inconspicuous, and the image quality is improved. However, when the low-density halftone dot portion is subjected to the smoothing process, the data may be distorted, the density may be reduced, and the data may disappear at worst. Therefore, the selector 72 switches between the data M after smoothing and the data L = N without smoothing by the smoothing selection 73. The smoothing selection 73 selects data that is not to be smoothed in the halftone dot portion to avoid unnecessary density reduction. When “automatic” is designated, the smoothing selection 73 automatically switches the selector based on the detection result I of the halftone dot detection 65. It is possible to cope with a low-density halftone dot, which is a part that is not desired to be smoothed, and other parts in one image. When the user does not want to perform the smoothing, the user may specify “select” and “dot”. In this case, the smoothing selection 73 sets the selector 72 to output O = unsmoothed image data L = N. When the user wants to perform smoothing, the user only needs to specify “select” and “character”. In this case, the smoothing selection 73 sets the selector 72 to output O = smoothed image data M.
[0109]
The output J of the AND operation 69 is a binary signal that is either a high level 1 representing show-through or a low level 0 without show-through, that is, binary data, and represents a binary show-through image. It is also an area signal indicating a show-through area. This is show-through image (binary) data R. When the output J of the AND operation 69 is at a high level 1 representing show-through, the density conversion 77 outputs the multi-value input data Din (show-through multi-value image data) of the pixel of interest as it is, and If the output J is at low level 0 indicating no show-through, the image data Din of the target pixel is changed to a set low level K corresponding to the background level and output (Q).
[0110]
When the generation of the three sets of image data (O, Q, R) and the writing to the MEM are completed, the MEM includes an original image and three sets of images (O, Q, R) for each page image. There are four sets of image data. Here, the system controller 1 first executes “show-through removal display” PrD on the original of the first page in accordance with the show-through removal condition held by the operation board 20 in the show-through removal condition register.
[0111]
11 to 15 show an outline of the process of “show-through removal display” PrD. First, reference is made to FIG. If the display image selection in the show-through removal condition is a display of “only the image after removal” and the display mode selection is “identify the image after removal and the show-through image”, the system controller 1 Then, the image data R of the show-through image (binary) is read out from the MEM via the CDIC, and the “1” pixel is changed to a show-through part display color (for example, red) in the show-through removal condition by IPP. (Step 3), synthesizes it with the image data O of the corrected image (changes the image data at the corresponding position to red display data; Step 4), and reduces the image data to the size to be displayed on the liquid crystal display 79 (image data) Is thinned out (step 5), and transferred to the operation board 20 via the CDIC and IMAC for display (step 6).
[0112]
In the following, the word "step" is omitted in parentheses, and only the step number is written.
[0113]
When the display mode selection is “as image”, the system controller 1 reads out the image data O of the image after the show-through removal, that is, the corrected image from the MEM via the IMAC and the CDIC, and displays the image data O on the liquid crystal display 79 by the IPP. The image is reduced to the size to be displayed (7), transferred to the operation board 20 via CDIC and IMAC and displayed (8).
[0114]
Referring to FIG. 12 as well, the display image selection in the show-through removal condition is the display of “original and removed image”, and the display mode selection is “identify the removed image and show-through image”. And the system controller 1 reads out the image data R of the show-through image (binary) from the MEM via the IMAC and the CDIC, and removes the pixel “1” by IPP from the show-through portion in the show-through removal condition. A designated display color image S changed to a display color (for example, red) is made (13A), which is combined with the image data of the original image (changed to the sum data obtained by adding red data to the image data at the corresponding position; 14A). Then, the image data is reduced to less than half the size of the image displayed on the liquid crystal display 79 (image data is thinned out) (15A), transferred to the operation board 20 via the CDIC and IMAC, and transferred to the left half area (image). Rather, it causes the display on the left half display data storage area) of the display surface size larger than one screen display memory (storing and displaying) (16A). Further, the designated display color image S is combined with the image data O of the corrected image (the image data at the corresponding position is changed to red display data; 14B), and reduced to less than half the size of the image displayed on the liquid crystal display 79. (15B), the data is transferred to the operation board 20 via the CDIC and IMAC, and displayed in the right half area (the left half display data storage area on the display memory) (16B).
[0115]
If the display mode selection is “as the image”, the system controller 1 reads out the image data of the original image from the MEM via the IMAC and the CDIC, and reduces the image data to less than half the size of the image displayed on the liquid crystal display 79 by the IPP. The image is reduced (17A), transferred to the operation board 20 via CDIC and IMAC, and displayed in the left half area (18A). Further, the image data O of the image after the show-through removal, that is, the corrected image is read from the MEM via the IMAC and the CDIC, and reduced to less than half the size of the image displayed on the liquid crystal display 79 by IPP (17B). The data is transferred to the operation board 20 via the CDIC and the IMAC, and is displayed in the right half area (18B).
[0116]
Referring also to FIG. 13, if the display image selection in the show-through removal condition is a display of “the original image only” and the display mode selection is “identify the after-removal image and the show-through image”, The system controller 1 reads out the image data R of the show-through image (binary) from the MEM via the IMAC and the CDIC, and uses the IPP to set the pixel of “1” to the show-through portion display color in the show-through removal condition. (For example, red) (23), which is combined with the image data of the original image (changed to the sum of the image data at the corresponding position and the red data; 24), and the image is displayed on the liquid crystal display 79. (25), transferred to the operation board 20 via CDIC and IMAC and displayed (26).
[0117]
If the display mode selection is “as image”, the system controller 1 reads out the image data O of the original image from the MEM via the IMAC and the CDIC, and reduces the size to the size to be displayed on the liquid crystal display 79 by the IPP. (27), transferred to the operation board 20 via the CDIC and IMAC and displayed (28).
[0118]
Referring to FIG. 14 as well, if the display image selection in the show-through removal condition is a display of “show-through image only”, the system controller 1 outputs the show-through image (multi-valued) via the IMAC and the CDIC. The image data Q is read from the MEM, reduced to a size for displaying an image on the liquid crystal display 79 by IPP (37), and transferred to the operation board 20 via CDIC and IMAC for display (38).
[0119]
Referring to FIG. 15 as well, the display image selection in the show-through removal condition is a display of “after removal & show-through”, and the display mode selection is “identify the after-removal image and show-through image”. And the system controller 1 reads out the image data R of the show-through image (binary) from the MEM via the IMAC and the CDIC, and removes the pixel “1” by IPP from the show-through portion in the show-through removal condition. A designated display color image S changed to a display color (for example, red) is obtained (43A), which is combined with the image data of the original image (changed to sum data obtained by adding red data to the image data at the corresponding position; 44A). Then, the size is reduced to less than half the size of the image displayed on the liquid crystal display 79 (45A), transferred to the operation board 20 via CDIC and IMAC, and displayed in the left half area (46A). Further, the image data Q of the show-through image (multi-valued) is read from the MEM via the IMAC and the CDIC, and reduced to less than half the size of the image displayed on the liquid crystal display 79 by IPP (45B). The data is transferred to the operation board 20 via the IMAC and displayed in the right half area (46B).
[0120]
If the display mode selection is “as the image”, the system controller 1 reads out the image data O of the corrected image from the MEM via the IMAC and the CDIC, and the half or less of the size of the image displayed on the liquid crystal display 79 by the IPP. (47A), transferred to the operation board 20 via CDIC and IMAC, and displayed in the left half area (48A). Further, the image data Q of the show-through image (multi-valued) is read out from the MEM via the IMAC and the CDIC, and reduced to less than half the size of the image displayed on the liquid crystal display 79 by IPP (47B). The data is transferred to the operation board 20 via the IMAC and displayed in the right half area (48B).
[0121]
One or two or three of the original image, the corrected image, and the show-through image (binary, multi-value) (for example, a correction in which the original image and the binary show-through image are overlapped) is performed by the “show-through removal display” PrD. When the “image display” is displayed, the user can determine whether the corrected image is appropriate (appropriate for show-through removal). Here, when the user changes the show-through removal condition and touches the “OK” key 327, the operation board 20 updates and writes the show-through removal condition currently displayed on the liquid crystal display 79 to a register, and removes the show-through removal. A process re-execution command and a show-through removal condition are transmitted to the system controller 1. The system controller 1 re-applies the show-through removal processing by the IPP to the original image data, obtains a new corrected image, a show-through image (multi-valued), and a show-through image (binary), and updates and writes the updated image into the MEM. Then, the “show-through removal display” PrD is executed again under the show-through removal condition displayed on the liquid crystal display 79.
[0122]
When the user touches the “OK” key 313 while the image processed by the “show-through removal display” PrD is displayed on the liquid crystal display 79, when the system controller 1 recognizes this through the operation board 20, The system controller 1 reads the corrected image data O from the MEM via the IMAC and the CDIC, converts the corrected image data O into image data for recording suitable for printing by the printer 100 by the “image quality processing” 46 of the IPP, Print out. This printout is performed for the number of copies set in the copy input mode.
[0123]
When the next page key 315 is touched while the image processed by the “show-through removal display” PrD is displayed on the liquid crystal display 79 and the original image data of the next page is in the MEM, the system controller 1 Then, the page display 317 of the liquid crystal display 79 of the operation board 20 is switched to the next page, and the show-through removal processing by the IPP is applied to the original image data of the next page, so that the corrected image and the show-through image (multi-valued) are displayed. Then, after the show-through image (binary) is updated and written into the MEM, the “show-through removal display” PrD is executed under the show-through removal condition displayed on the liquid crystal display 79.
[0124]
【The invention's effect】
The corrected image from which the low-density image (show-through, background stain) has been removed and the removed area image are displayed simultaneously or alternatively by the image output means (20). The user can visually confirm each image and confirm whether there is an erroneous image removal.
[Brief description of the drawings]
FIG. 1 is a front view showing the appearance of a copying machine having a composite function according to a first embodiment of the present invention.
FIG. 2 is an enlarged vertical sectional view schematically showing an image forming mechanism of the printer 100 shown in FIG.
FIG. 3 is an enlarged vertical sectional view showing an outline of a reading mechanism of the original scanner 10 shown in FIG.
FIG. 4 is a block diagram showing an outline of an image processing system of the copying machine shown in FIG. 1;
FIG. 5 is an enlarged plan view of a part of the operation board 20 shown in FIGS. 1 and 4.
6 is an enlarged plan view of the liquid crystal display 79 shown in FIG. 5, showing a state where an input screen for show-through removal setting is displayed.
FIG. 7 is a block diagram showing an outline of a part of processing functions of the IPP shown in FIG. 4;
8 is a block diagram illustrating an outline of a processing function of show-through removal 45 illustrated in FIG. 7;
9A is a plan view showing an image data distribution on a pixel matrix used in a density difference calculation matrix 61 shown in FIG. (B) is an explanatory diagram showing the content of the density difference calculation, and (c) is an explanatory diagram showing the content of the flatness detection.
FIG. 10A is a plan view illustrating pixels used in an averaging operation 61 shown in FIG. 8 and weights for the image data thereof. FIG. 9B is a plan view showing the count of the smoothing operation calculation used in the smoothing 71 shown in FIG. 8 on a pixel matrix.
11 is a flowchart showing a part of the outline of the processing control of “show-through removal display” PrD executed by the system controller 1 shown in FIG. 4 using the MEM, IMAC, CDIC, IPP, and operation board 20.
FIG. 12 is a flowchart illustrating another part of the outline of the “show-through removal display” PrD processing control.
FIG. 13 is a flowchart illustrating another part of the outline of the “show-through removal display” PrD processing control.
FIG. 14 is a flowchart illustrating another part of the outline of the “show-through removal display” PrD processing control.
FIG. 15 is a flowchart illustrating the rest of the outline of the “show-through removal display” PrD processing control.
[Explanation of symbols]
10: Color document scanner 20: Operation board
30: Automatic document feeder 34: Finisher
34hs: loading and lowering tray 34ud: lifting platform
34st: Sort tray group
100: color printer PC: personal computer
PBX: Switch PN: Communication line
102: Optical writing unit 103, 104: Paper cassette
105: registration roller pair 106: transfer belt unit
107: Fixing unit 108: Output tray
110M, 110C, 110Y, 110K: Photoconductor unit
111M, 111C, 111Y, 111K: photosensitive drum
120M, 120C, 120Y, 120K: developing unit
160: transfer conveyance belt ACP: image data processing device
CDIC: Image data interface control
IMAC: Image memory access control
IPP: Image data processor
231: platen glass 232: illumination lamp
233: First mirror 234: Second mirror
235: Third mirror 236: Lens
207: CCD 238: Running body motor
239: Reference white plate 240: Glass
241: Document tray 242: Pickup roller
243: registration roller pair 244: transport drum
245: Holding roller 246, 247: Discharge roller
248: Pressure plate also used as paper output tray
249: Base point sensor 250: Axis
251: Scale 260: Motor control unit

Claims (6)

The image information is converted into first image information in which image data of a low-density image satisfying the setting conditions on the image represented by the image information is corrected into image data representing an image in which the low-density image has been deleted, and the low-density image area is Low-density image removing means for generating the second image information shown; and image output means for simultaneously or alternatively displaying on the surface the corrected image represented by the first image information and the removal area image represented by the second image information; An image processing apparatus comprising: The first image information and the second image information are constituted by data having different image representations; the image output means combines and displays the corrected image represented by the first image information and the removal area image represented by the second image information. An image processing apparatus according to claim 1; 3. The image output unit according to claim 1, wherein the image information before conversion into the first image information, that is, the image represented by the original image information and the corrected image represented by the first image information are arranged side by side on the same plane. 4. The image processing apparatus according to claim 1. The multi-valued image data is converted into first image information composed of multi-valued image data obtained by correcting image data of a low-density image that satisfies a setting condition on an image represented by the multi-valued image data into image data representing an image from which the low-density image has been deleted. A low-density image removing unit that generates second image information composed of multi-valued image data indicating only the low-density image; and an image output unit that represents a removed image represented by the second image information on a surface. Image processing device. An image reading apparatus, comprising: the image processing apparatus according to claim 1; and a document scanner that reads a document and generates image data to supply the image data to the low-density image removing unit. An image processing device or an image reading device according to any one of claims 1 to 5, a printer for forming an image represented by image data for recording on paper, and converting the first image information into image data for recording. An image data processing means for providing the image data to the printer.

Images