JP2003136818A - Method and system for detecting image quality abnormality - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and a system for detecting image quality abnormality which can be incorporated readily even in an existing high speed printer and can detect an image quality abnormality in real time by on-line in units of page. SOLUTION: An image printed on a sheet at the printing section 12 of a printer 10 is read out photoelectrically by means of an image reader 34 to obtain an image which is then developed into an image memory 40. Based on a form frame image at a part common to respective pages included in the image PI developed into the image memory 40, and a reference form frame image FI held previously in a storage device 38, an image quality abnormality detecting section 42 detects the image quality abnormality of the image printed on the sheet.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image quality abnormality detecting method and an image quality abnormality detecting apparatus, and more particularly, to an image quality abnormality applicable to a printer which sequentially and continuously prints different information for each page having fixed information. The present invention relates to a detection method and an image quality abnormality detection device.

[0002]

2. Description of the Related Art Conventionally, various methods and apparatuses have been proposed for determining the print quality of an image printed by a printer. For example, there are JP-A-9-123533, JP-A-9-76605, and JP-A-9-131951.

In the technique disclosed in Japanese Unexamined Patent Publication No. 9-123533, bar code data moved by one dot for each page is added to user print information and printed, and the detection result and the original of the printed bar code data are added. The print quality is judged in real time by comparison with the data.

According to the technique described in Japanese Patent Laid-Open No. 9-131951, image data to be printed is subjected to expansion processing and contraction processing is used as mask data, and these are compared for each pixel with an image of a printed matter. By doing so, the print pixel outside the area and the pixel inside the area are detected, and the print quality is determined in real time based on the sum of the number of pixels of each pixel.

According to the technique disclosed in Japanese Patent Laid-Open No. 9-76605, the bitmap data of the test pattern and the image read out by the image sensor of the print output result of this data are subjected to template matching, and then the total number of non-matching pixels is summed up. The print quality is judged according to the size of. Further, when the overall image quality determination of the image is performed during the normal printing operation instead of the test pattern, the original image is compressed in the previous stage and then compared to enable high-speed processing.

[0006]

However, in the technique disclosed in Japanese Unexamined Patent Publication No. 9-123533, the print data generating means for adding the data printed by the user and the bar code data not directly related thereto to the user print information. , And a determination means for making a comparison / determination with the original bar code data are required, which cannot be easily incorporated into an existing printer device. In addition, the bar code data that the user does not want is printed on the paper, so that the appearance becomes worse. Furthermore, not only is the inspectable range within the page limited by the length of the barcode to be printed, but it is a condition for abnormal detection that continuous print quality failures occur over multiple pages. There is a problem that the print quality cannot be evaluated on a page-by-page basis.

Further, in the technique disclosed in Japanese Patent Laid-Open No. 9-131951, each page of a cut paper printer is different from that of a continuous paper printer in which the image print position deviation in the paper transport direction and the rotation direction is unlikely to occur due to the mechanism of the apparatus. Since each of them has a property that these deviations are likely to occur, when applied to a cut sheet printer, the quality of the printed matter is determined by the sum of the out-of-region pixels and the missing pixels, and therefore erroneous detection may occur easily. In addition, since the detection of abnormal pixels is performed with uniform sensitivity over the entire area, even if there are some stains or omissions on the page, there may be some points that are tolerated or that particularly high quality is required. However, since all abnormalities are detected uniformly, it is presumed that the desired performance cannot be obtained. In addition, when comparing images, it is necessary to sequentially obtain the original image data to be printed from the image processor, and there is a problem that it cannot be easily incorporated into an existing printer device.

Further, in the technique disclosed in Japanese Patent Laid-Open No. 9-76605, in the cut paper printer, the scanning range and the parameters for performing template matching between the image image read by the camera and the sensor and the original image are increased. By doing so, the processing time becomes extremely long. In order to perform this processing online without delay for ultra-high-speed printed paper, pipeline processing or parallel processing must be performed, so generally multiple pieces of extremely expensive image processing hardware are prepared. Or, it is necessary to set the inspection accuracy to a considerably low level. In addition, when performing template matching, it is necessary to acquire the original image data to be printed, and there is a problem that it cannot be easily incorporated into an existing printer device.

The present invention has been made in consideration of the above facts, can be easily incorporated into existing high-speed printers, and can be used for real-time image quality abnormality in page units at low cost. An object of the present invention is to provide an image quality abnormality detection method and an image quality abnormality detection apparatus that can detect the above.

[0010]

In order to achieve the above object, an invention according to claim 1 is a method for detecting an image quality abnormality in an image quality abnormality in an image printed on a print medium by a printing device for printing an image. The image is obtained by printing an image on a print medium by the printing device and photoelectrically reading the image printed on the print medium, and a portion common to each page existing in the image image. The image quality abnormality of the image printed on the print medium is detected based on the predetermined image image and the predetermined image image that is to be used as a reference.

A print medium printed by a printing device such as a printer device may contain a predetermined image that does not change for each page. Therefore, according to the first aspect of the invention, the image on the print medium printed by the printing device is photoelectrically read to obtain the image image, and the predetermined image image of the portion common to each page included in the image image is acquired. And the image quality abnormality of the image printed on the print medium is detected based on the predetermined image image that is to be the reference and is stored in advance in the storage device or the like. For example, binarization processing, edge detection, brightness histogram for a region near a predetermined image,
It is possible to detect the image quality abnormality by using image processing such as feature amount calculation.

As described above, since the image quality abnormality detection is performed on a predetermined portion (a predetermined image image of a portion common to each page) of the image printed on the print medium by the printing device,
Compared with the case where the image quality is detected for all the images, the time required for detecting the image quality abnormality can be shortened.

Further, by providing the printing device with an image reading means for reading a printing medium printed by the printing device, it is possible to easily incorporate the printing medium into an existing printer device.

Therefore, it can be easily incorporated into the existing high-speed printer, and the image quality abnormality can be detected on a page-by-page basis in real time at low cost.

As the predetermined image, for example, as in the invention described in claim 2, an image in which an area is designated in advance by the position and size of the rectangular frame may be used. As in the invention described in 3,
When there is a logo mark or company name that commonly exists for each page, an image image of the logo mark or company name may be used.

As the image image in which the position and size of the rectangular frame in the invention described in claim 2 are specified, for example, as in the invention described in claim 4, the printing position and size for each page An image image representing a fixed form frame whose print content does not change may be used. At this time, as the predetermined image image to be the reference, as in the invention described in claim 5, an image image obtained by presetting by the setting means for setting the form frame may be used.

Any one of claims 1 to 4 described above
In the invention described in the paragraph (3), the image image obtained by photoelectrically reading the image printed on the print medium in advance may be used as a reference image, as in the invention described in the sixth aspect. As in the invention described in Item 7,
A part common to each page is detected from an image image obtained by sequentially photoelectrically reading an image printed on a print medium by a printing device, and the image image of the common part is used as a predetermined image image to be a reference. You may use it.

When performing the setting by the setting means in the invention described in claim 5, as in the invention described in claim 8, among the image images representing a plurality of different form frames stored in advance. By selecting and setting the predetermined image image to be the reference from, it is possible to easily set the predetermined image image to be the reference.

Further, according to the invention described in any one of claims 1 to 8, as in the invention described in claim 9, a plurality of inspection target regions each including a predetermined image image included in the same page. The image quality abnormality may be detected for each of the above. At this time, as in the invention described in claim 11, the inspection target area precision setting means for setting the accuracy of the image quality abnormality detection for each of the plurality of inspection target areas detects the image quality abnormality with the detection accuracy set in advance for each inspection target area. You may make it detect.

Further, the invention according to any one of claims 1 to 9 is preset by the accuracy setting means for setting the detection accuracy of the image quality abnormality like the invention according to claim 10. The image quality abnormality may be detected with the detection accuracy.

Further, any one of claims 1 to 11
The invention according to claim 12 is, like the invention according to claim 12,
It is also possible to detect the image quality abnormality with the detection accuracy set in advance by the abnormality type setting means for setting the detection accuracy of the image quality abnormality for each type of image quality abnormality.

Further, any one of claims 1 to 12 is provided.
The invention according to claim is like the invention according to claim 13,
When an image quality abnormality is detected, the printing apparatus may be made to eject the print medium having the image quality abnormality to the unnecessary print medium discharge destination to stop the printing operation. By doing so, it is possible to prevent the print medium in which the image quality abnormality is detected from being mixed into the print medium after normal printing.

Further, in the invention described in any one of claims 1 to 13, as in the case of the invention described in claim 14, when an image having no portion common to each page is printed by a printer. Is to print a predetermined image for image quality inspection for each predetermined page and photoelectrically read the printed print medium to obtain an image image for image quality inspection, which should be used as a reference. The image quality abnormality may be detected periodically using the image image for the image quality inspection.

In the invention described in any one of claims 1 to 14, the image processing performed to detect the image quality abnormality is performed in advance as in the invention described in claim 15, for example. When using a print medium on which predetermined printing has been performed, it is possible to use an image image acquired in advance by photoelectrically reading an image representing the predetermined printing as mask data for image processing.

According to the invention described in claim 8 described above, like the invention described in claim 16, a paper feed tray in which different papers are loaded in a paper feed device for supplying papers as print media to the printing device. When there are a plurality of, and when printing an image image representing the different form frame for each paper feed tray, if the image image representing the form frame corresponding to each paper feed tray is stored in advance, Since the paper feed tray is specified when printing is performed by the printing apparatus, an image representing a form frame to be used as a reference is selected from the stored image images representing the form frame based on the specified paper feed tray. The image may be set.

Further, in the invention described in claim 14 described above, like the invention described in claim 17, the paper feeding device for feeding the paper as the printing medium to the printing device is loaded with different papers. When there are a plurality of paper trays and each of the paper feed trays is loaded with the paper for the image quality inspection, if the image image for the image quality inspection is stored in advance for each paper feed tray, Since the paper feed tray is specified when printing is performed by the printing apparatus, the image image for image quality inspection to be used as a reference from the stored image images for image quality inspection based on the specified paper feed tray. May be selected.

Further, in the invention according to any one of claims 1 to 17, as in the invention according to claim 18, an abnormality such as a paper jam occurs in the printing apparatus, and the printing apparatus When it becomes necessary to discharge the print medium remaining in the print medium to the unnecessary print medium discharge destination, when a printable print medium exists in the printing apparatus, a predetermined image for image quality inspection is printed on the print medium. And photoelectrically reading the image for image quality inspection on the printed print medium, based on the image image for image quality inspection obtained by the reading, and the image image for image quality inspection to be a reference, It is also possible to detect the image quality abnormality and discharge the print medium on which the image for image quality inspection is printed to the unnecessary print medium discharge destination. This makes it possible to confirm whether or not an image quality abnormality due to an abnormality in the printing apparatus has occurred in the printing apparatus.

According to a nineteenth aspect of the present invention, a light source for irradiating a print medium on which an image is printed with light and a transmitted light or a reflected light of the print medium are incident on the print medium to print an image. A reading unit that acquires an image image by photoelectrically reading, a storage unit that stores a predetermined image image that serves as a reference for a portion common to each page existing in the image printed on the print medium, and the reading unit. The predetermined image image in the acquired image image,
Detection means for detecting an image quality abnormality of the image printed on the print medium based on the predetermined image image to be the reference stored in the storage means.

According to the nineteenth aspect of the present invention, the light source irradiates the printing medium on which the image is printed with light, and the reading unit prints by transmitting transmitted light or reflected light of the printing medium. An image is obtained by photoelectrically reading the image printed on the medium.

The storage means stores a predetermined image image to serve as a reference for a portion common to each page existing in the image printed on the print medium.

Then, in the detecting means, a predetermined image image in the image image acquired by the reading means,
Abnormal image quality of the image printed on the print medium is detected based on the predetermined image image to be the reference stored in the storage means.

That is, as described in claim 1, the image quality abnormality detection is performed on a predetermined portion (a predetermined image image of a portion common to each page) of the image printed on the print medium by the printing apparatus. The time required for abnormality detection can be shortened compared to the case of detecting image quality abnormality for all images, and the image reading means for reading the print medium printed by the printing device is printed. If it is provided in the device, it can be easily incorporated into an existing printer device.

The invention described in claim 19 may further include notifying means to notify the detection result of the image quality abnormality as in the invention described in claim 20.

Further, the invention according to claim 19 or claim 20, like the invention according to claim 21, further comprises setting means for setting a predetermined image image to be a reference to be stored in the storage means. You may

The invention according to any one of claims 19 to 21 may further include accuracy setting means for setting the detection accuracy of the detecting means, as in the invention according to claim 22. May be.

Further, according to the nineteenth to twenty-second aspects of the present invention, like the invention of the twenty-third aspect, a printing means for printing the image on a printing medium and a discharging means for discharging the printing medium. By providing the light source and the reading unit on the transport path for transporting the print medium from the printing unit to the discharging unit of the printing apparatus including the above, it is possible to easily incorporate the light source and the reading unit into the existing printer apparatus as described above. Become.

[0037]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an example of an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows a schematic configuration of a printer according to an embodiment of the present invention, a peripheral device of the printer, and an image quality abnormality detecting device incorporated in the printer. The solid arrows in FIG. 1 indicate the flow of control information, the dotted arrows indicate the flow of image data, and the alternate long and short dash arrows indicate the sheet conveyance path.

As shown in FIG. 1, a host computer 22 connected to a storage device 24 for accumulating image data.
Are connected to the printer controller 20, and the printer controller 20 is connected to the printer device 10.

The printer device 10 includes the printer device 10
A control unit 14 that controls the entire system and a printing unit 12 that prints on a sheet as a printing medium are included.

The printer unit 10 includes a paper printing unit 12
The sheet feeding device 16 for supplying the sheet to the sheet feeding device 16 and the sheet discharging device 18 for discharging the sheet printed by the printing unit 12 are connected. Then, the printing based on the image data is performed and the sheet is conveyed to the paper discharge device 18.

Image data for printing is stored in the storage device 24, and the image data accumulated in the storage device 24 is sent to the printer device 10 by the host computer 22 to issue a print job execution request. It is sent to the printer device 10 via the controller 20. When the print job execution request is issued, the printer controller 20 issues a print start request to the control unit 14 of the printer device 10, generates original image data, and sends the original image data to the printing unit 12.

The control unit 14 sends a paper feed request to the paper feed device 16. As a result, the paper (blank paper BR) is conveyed from the paper feeder 16 to the printing unit 12 of the printer 10. In the printing unit 12, the printer controller 2
Based on the original image data ID sent from 0, printing is performed on the paper at an appropriate timing, and the paper P after printing is printed.
Are conveyed to the paper discharge device 18, and the paper discharge device 18 discharges the paper.

The paper feeding device 16 and the paper discharging device 18 are
As shown in FIG. 1, it may be independent of the printer device 10 or may be included inside the printer device 10. Further, in the present embodiment, the cut paper is shown as a premise, but continuous paper may be used. Further, the printer device 10 may be monochrome or color.

Next, the image quality abnormality detecting device 30 incorporated in the printer device 10 will be described.

FIG. 2 shows an example of a print output result obtained as a result of the printing operation of the printer device 10. Note that FIG. 2A shows the entire print output result, and FIG.
Shows a partially enlarged portion, and FIG. 2C shows a form frame portion. In such a form sheet, the information that changes for each page is often particularly important among the information drawn on the same page. For example, in FIG.
In the case of the bill form as shown in (A), this corresponds to customer information, monetary amount data, and the like. Generally, these forms are formed by surrounding important variable data with a form frame 26 as shown in FIG. Therefore, the image abnormality detecting apparatus 30 according to the present embodiment detects the image quality abnormality by using a common predetermined image that does not change from page to page such as the form frame 26 that surrounds important variable data.

The image quality abnormality detecting device 30 includes a light source device 32,
The image reading device 34, an information management unit 36, a storage device 38, an image memory 40, an image quality abnormality detection unit 42, and an interface 44 are included.

The light source device 32 and the image reading device 34 are provided on the paper transport path between the printer device 10 and the paper discharge device 18, and the printer output paper (printed paper is sequentially transported on the paper transport path. P) is irradiated with light from the light source device 32, and reflected light or transmitted light is emitted from the image reading device 3
The image printed on the paper by the image reading device 34 is acquired as a high-resolution image image PI. The read image image PI is output to the image memory 40.
As the image reading device 34, for example, an area camera, a line sensor, or the like can be used.

The storage device 38 stores a plurality of pre-registered / designated form frame images FI as image images to serve as a reference for image quality abnormality detection. In addition to the form frame image FI, for example, a logo mark, a company name, or the like may be stored as the image image to be used as the reference for image quality abnormality detection, and this may be used for image quality abnormality detection.

The image quality abnormality detection unit 42 develops the form frame image FI stored in the storage device 38 on the image memory 40 through the information management unit 36, and the form frame vicinity region 28 of the form frame image FI (see FIG. Image processing such as binarization, edge detection, brightness histogram, and feature amount extraction is performed on the hatched portion (B)) to output an abnormal blank sheet,
Abnormal image quality such as band-shaped color loss, black line, fog, and blurring is detected with preset accuracy. At the same time, image processing such as affine transformation is performed to detect abnormal rotation deviation of the image on the paper, positional deviation, and expansion / contraction of the image. Furthermore, when printing on a preprinted sheet (preprinted sheet) on which a predetermined printing has been performed in advance, the image image of the preprinted sheet is read in advance by the image reading device 34 and stored in the storage device 38. When performing image processing, this image data can be used as mask data for the image processing.

The user interface 44 is connected to the information management unit 36 and the image quality abnormality detection unit 42, and when the image quality abnormality detection unit 42 detects the above-mentioned abnormality, the type of the abnormality that has occurred, the location where it occurred, the date and time, etc. are generated. The operator is informed of the situation, and is provided with a display device such as a liquid crystal display device and an operating device such as a numeric keypad for displaying various information and performing various settings. Further, the user interface 44 is configured to select and set a predetermined image image to be a reference for detecting the image quality abnormality such as the form frame stored in the storage device 38 used when detecting the image quality abnormality.

In the information management unit 36, the image quality abnormality detection unit 42
When the above-mentioned abnormality is detected by, the information such as the occurrence status of the above-mentioned abnormality notified by the user interface 44 is acquired and controlled to be stored in the storage device 38 as a log. When the operation device included in the user interface 44 gives an instruction to confirm the log information, the log is read from the storage device 38 and displayed on the display device included in the user interface 44. . This allows the user to check the log information.

If the user interface 44 and the control unit 14 can be connected to the control unit 14 of the printer 10 so that the print job information can be acquired, the operator is notified and the log is output. When storing,
Information such as a job or sheet in which an abnormality is detected may also be notified. In this case, when the image quality abnormality detecting unit 42 detects an abnormality, the control unit 1
It is possible to stop the printing operation by 4 and to discharge the abnormal output paper to the paper discharge device 18 to the unnecessary paper discharge destination.

Next, an example of the image quality abnormality detection processing by the image quality abnormality detection device 30 configured as described above will be described with reference to the flowchart of FIG.

In step 100, the printer device 10 prints an image based on the image data ID on a sheet and the output page P conveyed to the sheet discharge device 18 is irradiated with light from the light source device 32. As a result, the transmitted light or the reflected light of the output page P is read by the image reading device 34, so that the image of the output page P is photoelectrically read, and the image image PI is acquired.

In step 102, the image image PI acquired by the reading of the image reading device 34 is expanded in the image memory 40, the form frame 26 is detected by the image quality abnormality detecting section 42, and it is determined whether or not the form frame 26 is detected. It is determined by the image quality abnormality detection unit 42. If the determination is affirmative, the process proceeds to step 104, and the image quality abnormality detection unit 42 stores the form frame image FI stored in the storage device 38 through the information management unit 36 in the image memory 40 in advance. It is determined whether or not the form frame image FI stored in the device 38 is set. If the determination is affirmative, the process proceeds to step 106, and the image quality abnormality detection unit 42 determines whether there is an uninspected form frame for image quality abnormality detection. If the determination is negative, the process returns to step 100 and the processing from step 100 is repeated. If the determination is positive, the form frame image FI previously stored in the storage device 38 is stored in the image memory 40. After being expanded, the process proceeds to step 108. The expansion of the form frame FI is performed by the user interface 4
4, the form frame set in advance is expanded.

In step 108, the image quality abnormality detecting section 42
The image quality inspection registration information (information for detecting an abnormal image quality such as abnormal white paper output, band-shaped white spots, black lines, fog, and fading with a preset accuracy) is registered by the information management unit 36. To be done.

In step 110, the image image PI acquired by the image reading device 34 is subjected to the image processing as described above by the image quality abnormality detecting section 42, and the image image PI subjected to the image processing and the image data PI are stored in advance. Device 3
8 is compared with the form frame image FI stored in the image memory 8 and expanded in the image memory 40 based on the image quality inspection registration information to detect the image quality abnormality.

In step 112, the image quality abnormality detecting section 42 determines whether or not the inspection result is normal. That is, as a result of the image quality abnormality detection performed in step 110, the image quality abnormality detection unit 42 determines whether the image quality is normal. When the determination is affirmative, that is, when there is no image quality abnormality, the process returns to step 106 and the above-described processing is repeated. For example,
The image quality abnormality is detected as shown in FIG. FIG. 2C shows an example of image quality abnormality. The upper part of FIG. 2C shows the state of black line detection, and the lower part of FIG.
A state of detection of band-shaped color loss is shown.

When the determination in step 112 is negative, that is, when it is determined that the image quality is abnormal, the process proceeds to step 114. In addition, when the determinations in step 102 and step 104 are negative, the process similarly proceeds to step 114.

In step 114, the user interface 44 reports the abnormality. That is, the abnormality is notified to the user by displaying the type of the abnormality detected by the image quality abnormality detection unit 42, the occurrence location, the occurrence status such as the date and time on the display device or the like.

In step 116, the information management unit 36 outputs the instruction information for ejecting the abnormal paper to the unnecessary paper discharge destination to the control unit 14 of the printer device 10, so that the abnormal paper is controlled by the control of the control unit 14. The paper is discharged to the unnecessary paper discharge destination, and the printer device 10 is stopped in step 118.

Then, in step 120, information relating to the abnormality detected by the image quality abnormality detecting section 42 (for example, the type of the abnormality, the occurrence location, the occurrence status such as date and time, etc.) is stored in the storage device 38 as log information. It

As described above, in the image quality abnormality detecting device 30 according to the present embodiment, since the image reading device 34 for detecting the image quality abnormality is provided between the printer device 10 and the paper discharge device 18, high speed printing is performed. It is possible to perform 100% inspection by following the speed at which the paper is output from the printer device 10.

Further, when handling a high-definition and wide-range image, the image processing usually requires a huge amount of time or requires a plurality of expensive dedicated image processing hardware. The abnormality detection device 30 can be collectively processed by inexpensive hardware such as one personal computer. Further, in the image quality abnormality detection processing, the form frame fixed for each page is set as the inspection target area, so that the processing can be performed in a shorter time than in the case where the image quality abnormality is detected in the entire area.

Further, for an ultra-high speed printer using wide continuous paper which requires higher speed processing, the same inspection can be performed by providing a plurality of these image abnormality detecting devices 30 and operating them in parallel. In addition, it is possible to inspect both the front surface and the back surface of a printer device that performs double-sided printing.

Next, the flow of processing performed by the printer device 10 and the image quality abnormality detection device 30 when performing pre-registration of form frames will be described with reference to the flowcharts of FIGS. 4 and 5.

FIG. 4 is a flow chart showing the pre-registration process of the form frame when the operator registers itself.

First, the operator instructs the start of the form information registration work through the user interface 44, and the processing of the flowchart shown in FIG. 4 is started. In step 200, it is determined whether or not the form is scanned and registered. It The determination is performed by the user operating the user interface 44 to determine whether the sample framed form is printed by the printer device 10 and registered or the already printed framed form is registered. .

In step 200, the determination is negative, that is,
When the sample framed form is to be printed on the printer device 10 and registered, the process proceeds to step 202,
Select a job for sample output and instruct to start printing. The sample output job can be stored in the storage device 24 or the storage device 38 in advance, and the printer controller 20 or the user interface 44 can be operated to selectively output the job. As a result, in step 204, the desired sample job sheet is printed by the printing unit 12, is conveyed to the paper discharge device 18, and proceeds to step 206.

If the determination in step 200 is affirmative, that is, if the already-printed framed form is to be registered, the framed form paper prepared by the operator in advance is stored in the paper feeding device 16 in step 208. By setting the proper position and instructing the printer device 10 to start scanning by the printer controller 20 in step 210, the framed foam paper prepared in advance by the operator from the printer device 10 is conveyed to the paper ejection device 18. , Go to step 206. At this time, the printer device 10 simply ejects the paper without printing.

In step 206, the output page output from the printer device 10 is read by the image reading device 34, and the image image PI is acquired.

In step 212, the image quality abnormality detecting section 42 determines whether or not the inspection frame candidate is detected. In the determination, the image quality PI detected by the image reading device 34 is subjected to image processing such as edge detection and closed loop search by the image quality abnormality detection unit 42, and an inspection frame candidate that defines an area in which the image quality abnormality detection is performed is selected. It is done by searching.

If the determination in step 212 is affirmative,
That is, when the inspection frame candidate is detected, the process proceeds to step 214, the position and size of the detected inspection frame candidate are displayed on the user interface 44, and the process proceeds to step 216.

When the determination in step 212 is negative, that is, when the inspection frame candidate is not detected, the process proceeds to step 218, and the operator operates the user interface 44 to freely page the page. An arbitrary area inside is set as an inspection frame candidate, and the process proceeds to step 216. Note that step 212
The determination may be denied even when the operator desires to set the inspection frame candidate.

Subsequently, in step 216, the operator sets Enable / Disable settings for determining whether or not to inspect each frame from these inspection frame candidates, and Enable / Disable settings for each detectable image quality abnormality. , Stepwise setting of detection accuracy of image quality abnormality. After the setting of step 216 is performed for all the inspection frame candidates in one page, the process proceeds to step 220, the information is stored in the storage device 38, and the series of processes is ended.

That is, in the flow chart shown in FIG. 4, when there are a plurality of inspection frame candidates in the same page as shown in FIG. 2, Enable / Dis is set for each inspection frame candidate.
The operator can individually set the able setting, each detection item, detection accuracy, and the like.

Next, the case of automatically registering a form frame will be described with reference to the flowchart of FIG. In addition,
When automatically registering a form frame, an operator operates the user interface 44 in advance to set the mode to the automatic registration mode, whereby the form is automatically registered.

When the operator gives an instruction to start printing the job in the automatic registration mode in step 300, the printing operation is started by the printer device 10 in step 302. The print start instruction in the automatic registration mode can be configured to be issued by the printer controller 20 or the user interface 44.

In step 304, the output page P discharged from the printing section 12 is read by the image reading device 34, and is sequentially taken into the image memory 40 as the image image PI.

In step 306, the image image captured for each page is compared with the acquired image data of the past N-1 sheets for each pixel by the image quality abnormality detecting unit 42, and the common print portion is extracted. To be done. At this time, the expansion process may be added to the read image in consideration of the positional shift due to printing between the pages.

Subsequently, in step 308, the image quality abnormality detecting section 42 determines whether or not the number of read sheets acquired by the image reading device 34 is equal to or larger than a predetermined number and there is an inspection frame frame candidate. If the determination is negative, the process returns to step 304 again and the above-described processing is repeated. If the determination in step 308 is affirmative, step 310 is performed.
Move to.

In step 310, the position and size of the detected inspection frame candidate are displayed on the user interface 44, and the process proceeds to step 312, in which the operator performs inspection for each frame from these inspection frame candidates / Enable / Disable setting that decides not to execute, Enable / Disable setting for each detectable image quality abnormality, and stepwise setting of detection accuracy of image quality abnormality. After the setting of step 312 is made for all the inspection frame candidates in one page, the process proceeds to step 316, the information is stored in the storage device 38, and the series of processing is ended.

That is, also in the flow chart shown in FIG. 5, when there are a plurality of inspection frame candidates in the same page as shown in FIG. 2, Enable is set for each inspection frame candidate.
The operator can individually set / Disable setting, each detection item, detection accuracy, etc.

FIG. 6 shows an example of database items such as inspection areas and accuracy settings stored in the storage device 38. FIG. 6A shows an example of the form database, which corresponds to the form number, the form name, the registration date and time,
Image sizes, sample images, etc. are stored, and FIG. 6B shows an example of a frame database. Form numbers corresponding to frame numbers, positions, sizes, valid / invalid, detection accuracy (black line), detection accuracy (Band-shaped blank), detection accuracy (tip registration), detection accuracy (skew), etc. are stored.

FIG. 7 shows an example of the setting in the interface 44 when setting the database as shown in FIG. FIG. 7 shows an example of setting by software by a personal computer or the like. In this example, a column for displaying a capture image (capture image 46) is provided, and information such as a form number and registration date and time is displayed. It Further, setting items 48 and the like by the operator such as the form name and the inspection item are displayed, and the operator can check each item of the inspection item 50 for each frame (Frame 1 shown in FIG. 7) of which the image quality abnormality is to be detected. With respect to the above, various settings can be performed by operating the operation device of the user interface 44 (in this case, the keyboard of the personal computer). By using such a user interface 44, it is possible to set the detection accuracy for each image quality abnormality type for each detection target area (each frame) of the image quality abnormality.

In the above embodiment, when performing a print job of a form in which there is no form frame that can be registered for inspection on the page, for example, the inspection print pattern 52 as shown in FIG. 8 is used. It is possible to regularly check whether or not the image quality abnormality has occurred in the printer device 10 by configuring to print on the paper dedicated to the image quality inspection for every fixed number of pages between the pages of the job. . Then, for example, when there are a plurality of paper feed trays in which different papers are loaded in the paper feed device 16, a paper dedicated to the image quality inspection is loaded in each paper feed tray.
If the image quality inspection print pattern 52 corresponding to the image quality inspection dedicated paper loaded in each of the paper feed trays is stored in the storage device 38 in advance, the paper feed tray can be specified when the printer 10 prints. Therefore, based on this, it is possible to automatically set a print pattern for image quality inspection to be a reference for image quality detection from print patterns for image quality inspection stored in the storage device 38.

When using a paper for image quality inspection,
The image quality inspection paper (the paper on which the inspection pattern as shown in FIG. 8 is printed) passes through the image reading device 10 and then is directed to the unnecessary paper discharge destination of the paper discharge device 18 by the control of the control unit 14 of the printer device 10. By ejecting, it is possible to prevent the image quality inspection paper from being mixed with a normal print output. In FIG. 8, the print pattern 52 for inspection is shown.
As an example, a grid pattern is shown.

In the above embodiment, the form frame to be used as the reference for detecting the image quality abnormality is automatically registered from the paper printed by the printer device 10. However, the registration is automatically performed. The way to do
The present invention is not limited to this, and for example, there are a plurality of paper feed trays in which different papers are loaded in the paper feed device 16,
When printing different form frames for each paper feed tray,
If the form frame image is stored in advance in the storage device 38 for each of the paper feed trays, the paper feed tray is specified when printing is performed by the printer device 10. It is also possible to automatically set a form frame image to be a reference for image quality detection from the stored form frame images.

The image quality abnormality detection timing of the image quality abnormality detection apparatus 30 according to the present embodiment is determined by the printer apparatus 10.
It may be performed when an abnormality such as a paper jam occurs inside. For example, when an abnormality occurs in the printer device 10 and it becomes necessary to discharge the paper remaining in the printer device 10 to the unnecessary paper discharge destination, if there is printable paper in the printer device 10, The printer pattern 52 for inspection, which is stored in advance in the storage device 38, is printed on a sheet, and the printed sheet is photoelectrically read by the image reading device 34 to obtain an image image. The abnormality in image quality may be detected based on the stored printer pattern for inspection that serves as a reference. As described above, by performing the image quality abnormality detection when the abnormality occurs in the printer device 10, it is possible to confirm whether the image quality abnormality has occurred due to the abnormality of the printer device 10. At this time, if the paper used for the image quality detection is discharged to the unnecessary paper discharge destination of the paper discharge device 18, the unnecessary paper can be eliminated.

[0091]

As described above, according to the present invention, the image quality abnormality detection is performed on a predetermined image of the image printed on the print medium by the printing apparatus. Therefore, it is necessary when performing the image quality abnormality detection. Can be performed in a short time. The image quality abnormality can be detected only by providing an image reading unit or the like for reading the print medium printed by the printing device in the printing device. Therefore, it is possible to easily incorporate the image quality into an existing printer device.

[Brief description of drawings]

FIG. 1 is a block diagram showing an outline of a printer device and an image quality abnormality detection device according to an embodiment of the present invention.

FIG. 2 is a diagram showing an example of a print output result obtained as a result of a print operation of the printer device according to the embodiment of the present invention.

FIG. 3 is a flowchart showing an example of the flow of image quality abnormality detection processing by the image quality abnormality detection apparatus according to the embodiment of the present invention.

FIG. 4 is a flowchart showing a pre-registration process of a form frame when an operator registers himself / herself.

FIG. 5 is a flowchart showing a pre-registration process of a form frame in the case of automatically registering the form frame.

FIG. 6 is a diagram showing an example of database items such as inspection areas and accuracy settings stored in a storage device of the image quality abnormality detection device.

FIG. 7 is a diagram showing an example of settings in an interface when setting a database.

FIG. 8 is a diagram showing an example of an inspection print pattern 52.

[Explanation of symbols]

10 Printer device 12 Printing department 16 Paper feeder 18 Paper ejection device 26 form frames 30 Image quality abnormality detection device 32 light source device 34 Image reader 36 Information Management Department 38 storage device 40 image memory 42 Image quality abnormality detection unit 44 User Interface

Claims (23)

[Claims] 1. A method of detecting an image quality abnormality in an image printed on a print medium by a printing device for printing an image, comprising: printing an image on the print medium by the printing device; An image image is obtained by photoelectrically reading the image printed on, based on a predetermined image image of a portion common to each page existing in the image image, and the predetermined image image to be a reference held in advance. And detecting an image quality abnormality of an image printed on a print medium. 2. The image quality abnormality detection method according to claim 1, wherein the predetermined image image is an image image in which a region is designated in advance by the position and size of a rectangular frame. 3. The image quality abnormality detection method according to claim 1, wherein the predetermined image image is an image image including at least one of a logo mark and a company name that are commonly present in each page. . 4. The image image in which the area is designated is an image image showing a fixed form frame in which the print content including the print position and size for each page does not change. Image quality abnormality detection method. 5. The image quality abnormality detection according to claim 4, wherein the predetermined image image to be the reference is an image image obtained by presetting by the setting unit for setting the form frame. Method. 6. The image image to be the reference is an image image obtained by photoelectrically reading an image printed in advance on a print medium. 2. The image quality abnormality detection method according to item 1. 7. The predetermined image image to be the reference is common to each page detected photoelectrically by sequentially reading images on a printing medium printed by the printing device and detecting the image image obtained by the reading. The image quality abnormality detection method according to any one of claims 1 to 4, wherein the image is a partial image. 8. The image quality abnormality detection method according to claim 5, wherein the setting by the setting unit is performed by selecting from a plurality of prestored image images representing different form frames. . 9. The method according to claim 1, wherein the abnormal image quality is detected for each of a plurality of inspection target areas including the predetermined image image included in the same page. The image quality abnormality detection method according to item 1. 10. The detection of the image quality abnormality is performed with a detection accuracy preset by an accuracy setting unit that sets the image quality abnormality detection accuracy. The image quality abnormality detection method described. 11. The detection accuracy of the image quality abnormality in the plurality of inspection target areas is set in advance by the inspection target area accuracy setting means for setting the image quality abnormality detection accuracy for each inspection target area. The image quality abnormality detection method according to claim 9, wherein 12. The detection of the image quality abnormality is performed with the detection accuracy set in advance by an abnormality type setting unit that sets the detection accuracy of the image quality abnormality for each type of image quality abnormality. 11. The image quality abnormality detection method according to any one of 11 above. 13. When the abnormal image quality is detected, the printing apparatus is caused to eject the print medium having the abnormal image quality to an unnecessary print medium ejection destination, and stop the printing operation. The image quality abnormality detection method according to any one of claims 1 to 12. 14. When printing an image image which does not have a portion common to each page by the printing device, a predetermined image for image quality inspection is printed for each predetermined page,
The image quality inspection image on the printed print medium is photoelectrically read, and the image quality inspection image image obtained by the reading and the image quality inspection image image to be used as a reference are periodically read. The image quality abnormality detection method according to claim 1, further comprising detecting an image quality abnormality. 15. The image quality abnormality is detected by using image processing, and the image processing photoelectrically outputs an image representing the predetermined printing when printing is performed using a print medium on which the predetermined printing is performed. The image quality abnormality detection method according to any one of claims 1 to 14, wherein an image image acquired in advance by reading is used as mask data for the image processing. 16. An image image showing the form frame different for each paper feed tray, wherein a plurality of paper feed trays loaded with different papers are present in a paper feed device for supplying paper as a print medium to the printing device. When printing, the image image representing the form frame is stored in advance for each paper feed tray, and is stored based on the paper feed tray specified when printing is performed by the printing device. 9. The image quality abnormality detection method according to claim 8, wherein an image image representing the form frame to be a reference is set from among the image images representing the form frame. 17. A plurality of paper feed trays in which different papers are loaded are provided in a paper feed device that feeds paper as a print medium to the printing device, and the paper for image quality inspection is loaded in each paper feed tray. At this time, the image image for image quality inspection is stored in advance for each paper feed tray, and is stored based on the paper feed tray specified when printing is performed by the printing device. 15. The image quality abnormality detecting method according to claim 14, wherein the image image for image quality inspection to be used as a reference is selected from among the image images for image quality inspection. 18. Printing capable of printing in the printing device when an abnormality occurs in the printing device and it is necessary to discharge the print medium remaining in the printing device to an unnecessary print medium discharge destination. When a medium is present, a predetermined image quality inspection image is printed on the print medium, the image quality inspection image on the printed print medium is photoelectrically read, and the image quality inspection image obtained by the reading is printed. The image quality abnormality is detected based on the image image and the image image for the image quality inspection to serve as a reference, and the print medium on which the image for the image quality inspection is printed is discharged to the unnecessary print medium discharge destination. The image quality abnormality detection method according to any one of claims 1 to 17, characterized in that: 19. An image obtained by photoelectrically reading an image printed on a print medium by irradiating a light source for irradiating the print medium on which the image is printed and a transmitted light or a reflected light of the print medium. A reading means for obtaining an image; a storage means for storing a predetermined image image to serve as a reference for a portion common to each page existing in the image printed on the print medium; and the image in the image image obtained by the reading means. An image quality abnormality detection device comprising: a predetermined image image; and a detection unit that detects an image quality abnormality of an image printed on the print medium based on the predetermined image image that is to be a reference stored in the storage unit. 20. An informing means for informing a detection result of the detecting means is further provided.
The image quality abnormality detection device described in. 21. The image quality abnormality detection apparatus according to claim 19, further comprising a setting unit that sets the predetermined image image stored in the storage unit. 22. The image quality abnormality detection device according to claim 19, further comprising a precision setting unit that sets the detection precision of the detection unit. 23. Conveyance for conveying the print medium from the printing means to the discharge means of a printing apparatus including a printing means for printing the image on the print medium and a discharge means for discharging the print medium. 20. The light source and the reading means are provided on a path, wherein the light source and the reading means are provided.
The image quality abnormality detection device according to any one of 2 above.