JP7408610B2 - Image processing device, control method and program for the image processing device - Google Patents

Description

The present invention relates to an image processing device, a method for controlling the image processing device, and a program.

Conventionally, image reading devices used in copying machines, etc., transport originals one by one using an automatic document feeder (ADF, which will be described later), and read the image of the original using a CCD sensor fixed on the transport path. Yes (see Patent Document 1).

In the image reading apparatus having the above configuration, when conveying documents, a stack of documents without staples or clips may be stacked on the document tray, and a reading instruction may be issued.
The automatic document feeder is configured so that the document is separated and conveyed one by one by the separation mechanism in the conveyance section, so when the conveyance operation starts with a stack of bound documents loaded, the Load is applied to the binding section when the upper document is separated and transported.
This may cause the original to become wrinkled or torn. Further, if the bound documents are sent out without being separated, problems may occur such as paper jams on the conveyance path.

Therefore, in order to avoid such a situation, a device has been proposed that detects whether a document is bound with staples, clips, or the like.
For example, in order to determine whether a document stacked on a document tray has a binding section such as stapling, clipping, or gluing, the presence or absence of a binding section is determined by detecting changes in the height of the document as it is transported. There is a device having a configuration to do this (see Patent Document 2).

Japanese Patent Application Publication No. 2001-285595 Japanese Patent Application Publication No. 2004-182449

However, with the technology described in Patent Document 2 that detects changes in the height of a document during transport, if the document has folds or wrinkles before being transported, it may be incorrectly determined to be a bound document even though it is not bound. there is a possibility. Then, there was a problem in that no matter how many times the document was repositioned, false detections continued.
Another problem is that the conventional technology does not provide a method for reading a bound document after detecting a bound document, which is not user-friendly.
Another problem is that when a stapled bound document is detected, the automatic document feeder cannot read the bound document. Therefore, the job is either stopped, the document is placed on the document table, and reading is performed continuously from the beginning as a new job, or the user is not given appropriate operating instructions.

The present invention has been made to solve the above problems. An object of the present invention is to display a reception section that accepts an instruction to disable a function for detecting an abnormality in the shape of a document being transported , on the condition that an abnormality in the shape of the document being transported is detected. The aim is to provide a system that allows this.

An image reading apparatus of the present invention that achieves the above object has the following configuration.
The apparatus includes a display means, a conveyance means for conveying a document, a reading means for reading an image of the document conveyed by the conveyance means, and a detection means for detecting an abnormality in the shape of the document being conveyed by the conveyance means. and, on the condition that the detection means detects an abnormality in the shape of the document being transported, the display means accepts an instruction to disable a function for detecting an abnormality in the shape of the document being transported. It is characterized by displaying the section.

According to the present invention, a reception unit is displayed that accepts an instruction to disable a function for detecting an abnormality in the shape of a document being transported , on the condition that an abnormality in the shape of the document being transported is detected. Can be done.

1 is a diagram showing an example of the appearance of an image forming apparatus. FIG. 2 is a cross-sectional view showing a configuration example of an ADF and an image reading section. FIG. 1 is a block diagram showing the configuration of an image forming apparatus. FIG. 3 is a plan view illustrating the configuration of an operating section. FIG. 2 is a diagram illustrating a UI screen displayed on an LCD touch panel. FIG. 2 is a diagram illustrating a UI screen displayed on an LCD touch panel. 3 is a flowchart illustrating a method of controlling an image reading device. 3 is a flowchart illustrating a method of controlling an image reading device. FIG. 2 is a diagram illustrating a UI screen displayed on an LCD touch panel. FIG. 2 is a diagram illustrating a UI screen displayed on an LCD touch panel. 3 is a flowchart illustrating a method of controlling an image reading device. 3 is a flowchart illustrating a method of controlling an image reading device. FIG. 2 is a diagram illustrating a UI screen displayed on an LCD touch panel. FIG. 2 is a diagram illustrating a UI screen displayed on an LCD touch panel.

Next, the best mode for carrying out the present invention will be described with reference to the drawings.
<Description of system configuration>
[First embodiment]

FIG. 1 is a diagram showing an example of the appearance of an image forming apparatus according to this embodiment. In this example, an MFP (Multi Function Printer) that can perform a scan function, a copy function, a print function, a send function, etc. will be described as an example.
In FIG. 1, an image reading section 200, which is an image reading means, scans an image on a document by exposure light emitted from an illumination lamp and inputs the reflected light obtained by inputting the reflected light into a linear image sensor (CCD sensor) to obtain image information. into an electrical signal. The image reading section 200 further converts the electrical signal into a luminance signal consisting of each color of R, G, and B, and outputs the luminance signal as image data to a controller section 400, which will be described later.

A document is set on a document tray 30 of an automatic document feeder (hereinafter referred to as ADF) 100. When the user instructs to start reading from an operation unit 405, which will be described later, the controller unit 400 sends a document reading instruction to the image reading unit 200. Upon receiving this instruction, the image reading section 200 separates and feeds the originals one by one from the original tray 30 of the ADF 100, and performs an operation of reading the originals. Further, the original can also be read by placing it on an original platen glass, which will be described later. Image forming section 500 is an image forming device that forms image data received from controller section 400 on paper.

The image forming method in this embodiment is an electrophotographic method using a photoreceptor drum or a photoreceptor belt. Further, the image forming unit 500 includes a plurality of cassettes as a paper feed unit 504 that can accommodate different paper sizes or different paper orientations. Further, the paper after printing is discharged to the paper discharge unit 502 and the finisher unit 505.

(Configuration example of ADF100)
FIG. 2 is a cross-sectional view showing a configuration example of the ADF 100 and the image reading section 200 of this embodiment. The operation of the ADF 100 will be described below with reference to FIG.
In FIG. 2, the ADF 100 includes a document tray 30 on which a document S made up of one or more document sheets is loaded, and a separation device in which the document S protrudes from the document tray 30 and prevents it from advancing downstream before the document starts being conveyed. It has a pad 21 and a paper feed roller 1. Furthermore, the ADF 100 includes a document detection sensor 23 that detects that the document S is placed on the document tray 30, a distance sensor 22 that measures the distance between the document S and the top surface of the document S, and a distance sensor 22 that measures the distance between the document S and the top surface of the document S. It has a separate sensor 24 that detects passing.
The paper feed roller 1 falls onto the surface of the document S stacked on the document tray 30 and rotates. As a result, the topmost original in the stack of originals is fed. The document conveyed by the paper feed roller 1 is separated into one sheet by the action of the separation roller 2 and the separation pad 21. This separation is achieved by the well-known retard separation technique. At this time, if the separation sensor 24 cannot detect the document even after a certain period of time (t1) has elapsed since the start of conveyance, the driving of the paper feed roller 1 and the like is stopped. The fixed time (t1) until the stop is the addition of the expected time from the start of conveyance to the separation sensor 24 according to the conveyance speed and a sufficient time in consideration of the delay.

The document separated by the separation roller 2 and the separation pad 21 is conveyed to the registration rollers 4 by the conveyance roller pair 3, and the document is abutted against the registration rollers 4. As a result, the original is formed into a loop shape, and skew during transport of the original is eliminated. On the downstream side of the registration rollers 4, a paper feed path is arranged to convey the document that has passed through the registration rollers 4 toward the scanning glass 201.

The document sent to the paper feed path is sent onto the platen by the large roller 7 and the conveyance roller 5. Here, the large roller 7 contacts the panning glass 201. The original transported by the large roller 7 passes through the transport roller 6, moves between the roller 16 and the moving glass, and is ejected to the original ejection tray 31 via the ejection flapper and the ejection roller 8.

The ADF 100 shown in Fig. 2 is a type that reads the image on the back side of a document by reversing both sides, and by reversing the paper ejection roller 8 and switching the paper ejection flapper with the document caught in the paper ejection roller 8, Move the original to reversal path 19. The moved original is brought into contact with the registration rollers 4 from the reversing path 19, and the original is again formed into a loop shape, thereby eliminating skew during transport of the original. Thereafter, by moving the document again to the scanning glass 201 using the transport roller 5 and the large roller 7, it is possible to read the back side of the document with the scanning glass 201.

Further, the document tray 30 is provided with a guide regulating plate 15 that is slidable in the sub-scanning direction of the stacked document bundle, and a document width detection sensor ( (not shown) is provided.
The combination of the document width detection sensor and the pre-registration sensor 11 makes it possible to determine the document size of the document bundle stacked on the document tray 30. Further, it is also possible to detect the document length from the conveyance distance from the leading edge detection to the trailing edge detection of the document being conveyed by a document length detection sensor (not shown) provided in the conveyance path. Further, the document size can also be determined from the combination of the detected document length and the document width detection sensor.

Further, the distance sensor 22 is a sensor that measures the distance to the top surface of the original S loaded on the original tray 30. For example, by measuring the difference between the distance to the top surface of the document S measured before the start of transport for each document and the distance to the top surface of the document S measured after a certain period of time (t2) after the start of transport, stapling can be performed. It is possible to detect originals with abnormal shapes, such as those that are bound with paper. Further, by setting t1>t2, it is possible to detect an abnormality in the shape of the document before a jam occurs.

(Example of configuration of image reading unit 200)
The image reading unit 200 optically reads image information recorded on the document on the document table glass 202 by scanning the document in the sub-scanning direction indicated by the arrow in FIG. 1 with the scanner unit 209.
Further, regarding the originals on the ADF 100, the originals on the original tray 30 are conveyed one by one to the reading center position. Furthermore, the scanner unit 209 is moved to the reading center position of the large roller 7 of the ADF 100, and the document is read at the reading center position of the large roller 7. The original on the ADF 100 or the original on the original table glass 202 is read by the following optical system. This optical system includes a scanning glass 201, a document table glass 202, a scanner unit 209 having a lamp 203 and a mirror 204, mirrors 205 and 206, a lens 207, and a CCD sensor unit 210. The read image information is photoelectrically converted and input as image data to a controller unit not shown in FIG. Further, the white board 219 is a white board for creating reference data of white level by shading. In this embodiment, the CCD sensor unit 210 includes a color image reading (RGB) CCD (3 line sensor unit) 212 and a monochrome image reading CCD (1 line sensor unit) 211.

(ADF100 control block)
FIG. 3 is a block diagram showing the configuration of an image forming apparatus according to this embodiment.

In FIG. 3, the control blocks of the ADF 100 include a control means (hereinafter referred to as CPU) 300 which is a central processing unit, a read only memory (hereinafter referred to as ROM) 301, a random access memory (hereinafter referred to as RAM) 302, an output port, and Equipped with an input port. The ROM 301 stores control programs and fixed parameters, and the RAM 302 stores input data and work data. A motor 303 that drives various conveyance rollers, a solenoid 306, and a clutch 307 are connected to the output port, and various sensors 304 are connected to the input port.

The CPU 300 controls paper transport according to a control program stored in a ROM 301 connected via a bus line. The CPU 300 performs serial communication with a central processing unit (CPU) 321 of the image reading section 200 via a control communication line 351, and exchanges control data with the image reading section 200. Further, an image leading edge signal serving as a reference for the leading edge of the document image data is also notified to the image reading unit 200 through the control communication line 351.

Further, the CPU 300 notifies the image reading unit 200 of the values of various sensors 304 in accordance with control data from the CPU 321 of the image reading unit 200. Note that the values of the various sensors 304 include data measured by the distance measuring sensor 22 and distance data.

(Control block of image reading unit 200)
In the control block of the image reading section 200, 321 is a CPU, which performs all controls of the image reading section 200. A ROM 322 for storing programs and a RAM 323 for providing a work area are connected to the CPU 321. Note that the RAM 323 indicates a work area that also includes an area for nonvolatile storage.

326 is an optical system motor drive section, which is a driver circuit for driving the optical system drive motor. The image reading section 200 is connected to a lamp 203 and a CCD sensor unit 210 (a CCD 211 for reading a black and white image for the front image/a CCD 212 for reading a color image for the front image). The CPU 321 controls the optical system motor driver section 326 and controls the CCD sensor unit 210 via the image processing section 325 to perform image reading processing.

In order to realize paper transport, the CPU 321 sends a command regarding paper transport control to the CPU 300 for paper transport control of the ADF 100 via the control communication line 351 to instruct it. The instructed CPU 300 monitors each sensor 304 installed on the transport path and drives the transport motor 303, solenoid 306, and clutch 307, which are loads, thereby realizing paper transport. In this way, the CPU 321 controls paper transport by the ADF 100 and image reading by the image reading unit 200. 324 is a paper gap correction processing unit that performs paper gap correction.

The image signal formed on the CCD sensor unit 210 (either the color image reading (RGB) CCD 212 or the monochrome image reading CCD 211) by the lens 207 is converted into digital image data. The converted image data is further subjected to various image processing such as shading in an image processing unit 325 to detect and correct streak images on the image data, and then written into an image memory 329.

The data written in the image memory 329 is sequentially transmitted to the controller section 400 through the image communication line 353 of the controller interface, which includes a clock signal line for image transfer. Furthermore, the timing of the image edge signal, which serves as a reference for the leading edge of the document image data, is notified to the controller section 400 through the control communication line 352 of the controller interface, with the timing adjusted by the CPU 321. Regarding the image tip signal notified through the communication line from the ADF 100, the timing is similarly adjusted by the CPU 321 of the image reading section 200, and the signal is notified to the controller section 400 through the control communication line 352 of the controller interface.

A CPU 321 controls an image processing section 325 connected to a control bus line. Further, the CPU 321 controls the CCD sensor unit 210 by transmitting a control signal to the CCD sensor unit 210 from the control communication line 354 via the image processing section 325. In the process of scanning a document image with the CCD sensor unit 210, it is read by the color image reading CCD 212 or the monochrome image reading CCD 211. Then, the read analog image signal for each line is output to the CCD control unit 213 from an image data communication line 214 or 215 including an image transfer clock signal line.

The analog signal is converted into digital image data in the CCD control section 213, and is transmitted to the controller section 400 through the image communication line 353, via the image memory 329, and the image communication line 355 including the clock signal line for image transfer.

The CPU 321 performs serial communication with the central processing unit (CPU) 401 of the controller section 400 via the image communication line 353, and exchanges control data with the controller section 400. The CPU 321 detects abnormalities in the shape of the document being transported in accordance with control data from the central processing unit (CPU) 401 of the controller unit 400. In detecting shape abnormalities, the difference between the distance to the top surface of the document S measured before the start of transport and the distance to the top surface of the document S measured after a certain time (t2) after the start of transport is calculated for each document. , if there is a difference (d1) of a certain value or more, it is determined that the document has an abnormal shape. Then, the CPU 321 notifies the central processing unit (CPU) 401 of the controller unit 400 of the determination result.

(control block of controller section 400)
The image processing controller unit 400 is a device that controls the entire image forming apparatus 2000 including the ADF 100, the image reading unit 200, and the image forming unit 500. The controller unit 400 includes a CPU 401, an image processing circuit 402, a scanner IF 403, an image memory 404, an operation unit 405, a RAM 406 that provides a work area, a ROM 407 that stores programs, a printer IF 408, and an HDD 409. Note that the RAM 406 represents a work area that also includes an area for nonvolatile storage.
Alternatively, the program may be loaded from the HDD 409 to the RAM 406 and executed by the CPU 401. Image data transmitted to the controller unit 400 through the image communication line 353 is stored in the image memory 404 through the scanner IF 403.

The image processing circuit 402 converts the image on the image memory 404 and returns it to the image memory 404 again. Image conversion processing performed by the image processing circuit 402 includes rotation processing for rotating an image in units of 32 pixels by 32 pixels by a specified angle, and resolution conversion processing for converting the resolution of an image.
Further, the image conversion processing performed by the image processing circuit 402 includes a scaling process of changing the size of an image, a matrix calculation of a multi-value input image, and a color space conversion process of converting a YUV image into a Lab image using an LUT. This color space conversion has a 3×8 matrix calculation and a one-dimensional LUT, and can perform known background removal and show-through prevention.

The operation unit 405 has a liquid crystal display (LCD), a touch panel input device pasted on the liquid crystal display, and a plurality of hard keys. Signals input through the touch panel or hard keys are transmitted to the CPU 401, and the liquid crystal display section displays function displays, image data, etc. for operation of the image forming apparatus.

An image tip signal is received from the image forming section 500 through the control communication line 356 of the controller interface. The data written to the image memory 404 based on the image tip signal that serves as the reference for the leading edge of the image data is sequentially transferred to the image forming unit via the printer IF 408 and the image communication line 357 of the controller interface including the clock signal line for image transfer. Sent to 500.

(Control block of image forming unit 500)
The image forming section 500 transports recording paper, prints image data on it as a visible image, and discharges the paper out of the apparatus. The image forming unit 500 includes a control unit 501 that controls the image forming unit 500, a paper feeding unit 504 that has multiple types of recording paper cassettes, and a marking unit 503 that has the function of transferring and fixing image data to the recording paper. has been done. It further includes a paper discharge unit 502 that has a function of outputting printed recording paper to the outside of the machine, and a finisher section (finisher unit) 505 that performs punching and sorting processing.

When the marking unit 503 is ready to form an image, the control section 501 transmits an image tip signal that serves as a reference for the tip to the controller section 400 through the control communication line 356 of the controller interface. The marking unit 503 then transfers and fixes the image data sent through the image communication line 357 of the controller interface onto the recording paper.

[Configuration of operation unit 405]
FIG. 4 is a plan view illustrating the configuration of the operating section 405 shown in FIG. 1.
In FIG. 4, 600 is an LCD touch panel, and main mode settings and status display are performed here. 601 is a numeric keypad for entering numbers from 0 to 9. Reference numeral 602 denotes an ID key, which is used when entering a department number and password mode when the device is under department management.

603 is a reset key for resetting the set mode, 604 is a guide key for displaying an explanation screen for each mode, and 606 is an interrupt key for performing interrupt copying. 607 is a start key for starting a copy or scan operation, and 608 is a stop key for stopping a job in progress.
Reference numeral 605 is a user mode key for entering the user mode screen. On the user mode screen, various settings regarding the device can be made. Reference numeral 609 is a power saving key; pressing this key will enter the power saving state, and pressing it again will return from the power saving state. Reference numeral 610 is a counter confirmation key, and when this key is pressed, a count screen displaying the total number of copies used so far is displayed on the LCD.

611 is an LED that indicates that a job is being executed or images are being stored in the image memory, 612 is an error LED that indicates that the device is in an error state such as a jam or a door open, and 613 is an LED that indicates that the main switch of the device is turned on. The power LED indicates the

[Copy screen]
5 and 6 are diagrams for explaining the UI screen displayed on the LCD touch panel 600 shown in FIG. 4. The UI screen shown in FIG. 5 shows an example of a copy screen.
As shown in FIG. 5, buttons for setting color selection 651, magnification 652, and paper selection 653 as basic settings are arranged as shown in FIG. 5, and their setting status is displayed at 650. Settings other than basic settings can be selected by pressing other functions 658.
Although not shown here, the other functions 658 include various functions such as page printing, page aggregation, and bookbinding. Among these functions, it is possible to create shortcut buttons on the copy screen for functions that the user uses frequently. Here, a duplex 654 for setting duplex printing and a density 655 for setting print density are arranged.
Further, a mixed original size 656 is arranged for reading originals of different sizes, and a bound original detection 657 is arranged for detecting whether the original S conveyed by the automatic document feeder 100 is an abnormally shaped original. .

The UI screen shown in FIG. 6 is a bound document detection setting screen that is displayed on the LCD touch panel 600 when the shortcut button for bound document detection 657 is pressed.
In FIG. 6, 701 is a button for enabling a bound document detection mode for detecting whether the document S conveyed by the automatic document feeder 100 in a copy job is a document with an abnormal shape. When the OK button 703 is pressed, data indicating validity/invalidity is stored in the RAM 406.
On the other hand, 702 is a button for disabling the bound document detection mode that detects whether the document S conveyed by the automatic document feeder 100 in a copy job has an abnormal shape. When the bound document detection mode is enabled, scanning of a job in which it is detected that a document with an abnormal shape is being conveyed is interrupted.

FIG. 7 is a flowchart illustrating a method of controlling the image reading device according to this embodiment. The processing shown in each step is realized by the CPU 401 of the controller unit 400 executing the control program read from the ROM 407 and developed in the RAM 406. Note that the series of processes related to FIG. 7 is started with the copy screen shown in FIG. 5 being displayed on the LCD touch panel 600 and with the binding document detection set to "detect".

In S701, the CPU 401 determines whether a copy job execution instruction has been accepted. If the CPU 401 determines that the request has been accepted (YES in S701), the process proceeds to S702. On the other hand, if the CPU 401 determines NO in S701, it repeats the process in S701 until determining that it has been accepted. Note that when the start key 607 is pressed by the user while the copy screen shown in FIG. 5 is displayed on the LCD touch panel 600, an instruction to execute the copy job is accepted.

In S702, the CPU 401 determines whether the document S is placed on the document tray 30. Note that the CPU 401 can determine whether the document S is placed on the document tray 30 by receiving a detection signal from the document detection sensor 23.

If it is determined in S702 that the document S is placed on the original document tray 30 of the CPU 401 (YES in S702), the process advances to S703. On the other hand, if the CPU 401 determines NO in S702, it ends the series of processing related to FIG.

In S703, the CPU 401 sets the value of a flag (hereinafter referred to as the scan end flag) for indicating whether a series of processes related to reading (scanning) the image of the document S has ended normally to "FALSE". (initialize. Note that the value of the scan end flag is stored in the RAM 406.

Note that when the value of the scan end flag is "TRUE", it indicates that the scan has ended normally. On the other hand, if the value of the scan end flag is "FALSE", this indicates that the scan did not end normally.
For example, when an instruction to cancel a scan is received, or when execution of a copy job is canceled, the CPU 401 determines that the scan did not end normally, and overwrites the value of the scan end flag with "FALSE". .
After executing the process in S703, the CPU 401 advances the process to S800. Note that details of the scan process in S800 will be described later.

Subsequently, in S704 of FIG. 7, the CPU 401 refers to the value of the scan end flag stored in the RAM 406 and determines whether the value of the scan end flag is "TRUE". If the CPU 401 determines that the result is "TRUE" (YES in S704), the CPU 401 advances the process to S705. On the other hand, if the CPU 401 determines NO in S704, the process advances to S706.

The CPU 401 reads the image data of the original S stored in the HDD 409 in S808, which will be described later, and temporarily stores it in the RAM 406 (S705). Then, the CPU 401 instructs the image forming unit 500 to perform printing processing based on the image data of the document S temporarily stored in the RAM 406 (S705).

After executing the process in S705, the CPU 401 advances the process to S706. In S706, the CPU 401 deletes the image data of the document S stored in the HDD 409 in S808 described above, and ends the series of processes related to FIG. 7. The details of the series of processes for receiving a copy job execution instruction and executing the received copy job have been described above.

[Series of processes related to scanning]
FIG. 8 is a flowchart illustrating a method of controlling the image reading device according to this embodiment. This example corresponds to the detailed procedure of a series of processing (S800) related to scanning by the CPU 401. Note that the processing shown in each step is realized by the CPU 401 of the controller unit 400 executing the control program read from the ROM 407 and developed in the RAM 406.

In S801, the CPU 401 sets (initializes) the value of the shape abnormality OFF flag to "FALSE" and advances the process to S802. Note that the shape abnormality OFF flag is a flag that indicates whether or not to continue scanning until the end of scanning when a shape abnormality is determined based on the change in distance between the distance sensor 22 and the top surface of the document S. It is about. Note that the value of the shape abnormality OFF flag is stored in the RAM 406. Here, if the value of the shape abnormality OFF flag is "TRUE", even if a shape abnormality of the document S is detected, scanning is continued until the scan is completed. On the other hand, if the value of the shape abnormality OFF flag is "FALSE", scanning is interrupted in accordance with the detection of the shape abnormality of the document S.

After executing the process in S801, the CPU 401 advances the process to S802. In S802, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to transport the original S placed on the original tray 30.

After executing the process in S802, the CPU 401 advances the process to S803. In S803, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to detect whether there is any abnormality in the shape of the document S conveyed in S802. The control unit (CPU 321) of the image reading unit 200 detects abnormalities in the shape of the document, and notifies the CPU 401 of the detection results. (S803)

After executing the process in S803, the CPU 401 advances the process to S804. When the CPU 401 receives the shape abnormality (YES in S804), the CPU 401 advances the process to S805. On the other hand, if the CPU 401 determines NO in S804, it advances the process to S808.

In S805, the CPU 401 refers to the setting information stored in the RAM 406 and determines whether the bound original detection mode is enabled. If the CPU 401 determines that the bound document detection mode is valid (YES in S805), the process proceeds to S806. On the other hand, if the CPU 401 determines in S805 that it is invalid, the CPU 401 advances the process to S818.

In S806, the CPU 401 refers to the value of the shape abnormality OFF flag stored in the RAM 406, and if it is determined that the value of the shape abnormality OFF flag is not "TRUE" (NO in S806), the process proceeds to S811.
On the other hand, if the CPU 401 determines YES in S806, it advances the process to S807. In S807, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to read the image of the transported document S.

After executing the process in S807, the CPU 401 advances the process to S808. The CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to transfer the read image data to the controller unit 400. Then, the CPU 401 stores the image data of the document S transferred to the controller unit 400 in the HDD 409 (S808).

After executing the process of S808, the CPU 401 advances to S809. The CPU 401 determines whether the document S is placed on the document tray 30 (S809). If the CPU 401 determines that the document S is placed on the document tray 30 (YES in S809), the process proceeds to S802. On the other hand, if the CPU 401 determines NO in S809, it advances the process to S810.

In S810, the CPU 401 overwrites the value of the scan end flag stored in the RAM 406 as "TRUE". After executing the process of S810, the CPU 401 ends the series of processes (S800) related to FIG. 8, and advances the process to S704 of FIG. 7 described above.

In S811, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to interrupt conveyance of the original. Along with the interruption of scanning, the conveyance of the original S and the reading of the image of the original S are stopped.

After executing the process in S811, the CPU 401 advances the process to S812. In S812, CPU 401 displays notification screen 900 shown in FIG. 9 on LCD touch panel 600.
Note that the notification screen 900 shown in FIG. 9 is a screen for prompting the user to place the document S on the document tray 30 of the ADF 100 again. Further, the notification screen 900 is a screen for prompting the user to continue scanning until the scanning is completed even if an abnormality in the shape of the document S is detected. Note that the CPU 401 displays a notification screen 900 on the LCD touch panel 600 as a screen for accepting that a bound document is not detected.

After executing the process in S812, the CPU 401 advances the process to S813. In S813, the CPU 401 determines whether an instruction to cancel the scan has been received. For example, the CPU 401 determines that the instruction to cancel the scan has been received in response to the user pressing the cancel button 901 on the notification screen 900. If the CPU 401 determines that the instruction to cancel the scan has been received (YES in S813), the CPU 401 ends the series of processes (S800) in FIG. 8, and proceeds to S704 in FIG. On the other hand, if the CPU 401 determines NO in S813, the process advances to S814.

In S814, the CPU 401 determines whether a scan restart instruction has been received. For example, the CPU 401 determines that the scan restart instruction has been received in response to the start key 607 on the operation unit 405 being pressed by the user.

If the CPU 401 determines that the scan restart instruction has been received (YES in S814), the process advances to S815. On the other hand, if the CPU 401 determines NO in S814, the process returns to S813.

In S815, the CPU 401 determines whether the bound original detection OFF button 902 on the notification screen 900 shown in FIG. 9 has been pressed. If the CPU 401 determines that the bound original detection OFF button 902 is pressed (YES in S815), the process advances to S816. On the other hand, in S815, the CPU 401 determines whether the user has selected to temporarily turn off the bound document detection mode.
For example, if the document detection OFF button 902 on the notification screen 900 shown in FIG. 9 is pressed, it is determined to be OFF. If the CPU 401 determines that the user has selected to temporarily turn off the bound document detection mode (YES in S815), the CPU 401 advances the S process to 816. On the other hand, if the CPU 401 determines NO in S815, the process advances to S817.
In S816, the CPU 401 overwrites the value of the shape abnormality OFF flag stored in the RAM 406 as "TRUE".

After executing the process in S816, the CPU 401 advances the process to S817.

In S817, the CPU 401 determines whether the document S is placed on the document tray 30. If the CPU 401 determines that the document S is placed on the document tray 30 (YES in S817), the process proceeds to S802.
On the other hand, if the CPU 401 determines NO in S817, it repeats the process in S817 until it determines that the object is placed.
In S818, the CPU 401 determines whether a paper jam has occurred in the ADF 100. For example, the CPU 321 of the image reading unit 200 determines that a jam has occurred if the separation sensor 24 cannot detect the document even after a certain period of time (t1) has passed since the start of conveyance.
Then, the CPU 321 notifies the CPU 401 of the controller section 400 of the jam occurrence. The CPU 401, which has been notified of the occurrence of a paper jam, determines that a paper jam has occurred. If the CPU 401 determines that a paper jam has occurred in the ADF 100 (YES in S818), the process proceeds to S819. On the other hand, if the CPU 401 determines NO in S818, the process advances to S807.

In S819, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to interrupt conveyance of the original. Along with the interruption of scanning, the conveyance of the original S and the reading of the image of the original S are stopped.

After executing the process in S819, the CPU 401 advances the process to S820. In S820, the CPU 401 determines whether the paper jam that occurred in the ADF 100 has been cleared. For example, the CPU 321 of the image reading unit 200 checks the values of the various sensors 304 notified from the CPU 300 of the ADF 100, and determines that the jam has been cleared if the document S is not detected after the separation sensor 24 (downstream).
Then, the CPU 321 notifies the CPU 401 of the controller section 400 that the jam has been cleared. The CPU 401, which has been notified of the paper jam, determines that the paper jam has been cleared. If the CPU 401 determines that the paper jam has been cleared in the ADF 100 (YES in S820), the process proceeds to S821. On the other hand, if the CPU 401 determines NO in S820, it repeats the process of S820.

In S821, the CPU 401 displays a notification screen 1000 shown in FIG. 10 on the LCD touch panel 600. Note that the notification screen 1000 shown in FIG. 10 is a screen for prompting the user to place the document S on the document tray 30 again.

After executing the process in S821, the CPU 401 advances the process to S822. In S822, the CPU 401 determines whether an instruction to cancel the scan has been received. For example, the CPU 401 determines that an instruction to cancel the scan has been received in response to the user pressing the cancel button 1001 on the notification screen 1000. If the CPU 401 determines that the instruction to cancel the scan has been received (YES in S822), the CPU 401 ends the series of processes (S800) in FIG. 8 and advances the process to S704 in FIG. On the other hand, if the CPU 401 determines NO in S822, the process advances to S823.

In S823, the CPU 401 determines whether a scan restart instruction has been received. For example, the CPU 401 determines that the scan restart instruction has been received in response to the start key 607 on the operation unit 405 being pressed by the user.

If the CPU 401 determines that the scan restart instruction has been received (YES in S823), the process advances to S809. On the other hand, if the CPU 401 determines NO in S823, the process returns to S822. The above is the details of the series of processes related to scanning (S800).
According to the first embodiment, if the shape of the transported document is not normal due to the condition of the document, an instruction to read the document is received from the user without detecting whether the shape of the document is abnormal. be able to.

[Second embodiment]
In this embodiment, the following example will be explained. First, after presenting to the user that the document is a stapled document, the user manually places the detected document on the document table without using the ADF 100. Next, an example will be described in which it is possible to accept an instruction to switch to continuous reading processing in which the user repeatedly presses the star button 607.
FIG. 11 is a flowchart illustrating a method for controlling an image reading apparatus according to this embodiment. Note that the processing shown in each step is realized by the CPU 401 of the controller unit 400 executing the control program read from the ROM 407 and developed in the RAM 406. Note that the series of processes shown in FIG. 11 is started with the copy screen shown in FIG. 5 being displayed on the LCD touch panel 600 and with the binding document detection set to detect. Note that the same steps as in FIG. 7 are given the same step numbers.

In S701, the CPU 401 determines whether a copy job execution instruction has been accepted. If the CPU 401 determines that the request has been accepted (YES in S701), the process proceeds to S1101. On the other hand, if the CPU 401 determines NO in S701, it repeats the process in S701 until determining that it has been accepted. Note that when the start key 607 is pressed by the user while the copy screen shown in FIG. 5 is displayed on the LCD touch panel 600, an instruction to execute the copy job is accepted.

In S1101, the CPU 401 sets the value of a flag (hereinafter referred to as the scan end flag) to indicate whether a series of processes related to reading (scanning) the image of the document S has ended normally to "FALSE". (initialize. Note that the value of the scan end flag is stored in the RAM 406.

Note that when the value of the scan end flag is "TRUE", it indicates that the scan has ended normally. On the other hand, if the value of the scan end flag is "FALSE", this indicates that the scan did not end normally. For example, when an instruction to cancel a scan is received, or when execution of a copy job is canceled, the CPU 401 determines that the scan did not end normally, and overwrites the value of the scan end flag with "FALSE". .

In S702, the CPU 401 determines whether the document S is placed on the document tray 30. Note that the CPU 401 can determine whether the document S is placed on the document tray 30 by receiving a detection signal from the document detection sensor 23.

In S702, if the CPU 401 determines that the document S is placed on the document tray 30 (YES), the CPU 401 advances the process to S1102. On the other hand, if the CPU 401 determines NO in S703, it advances the process to S1103.

In S1102, the CPU 401 sets the value of a flag (hereinafter referred to as a continuous reading flag) to indicate whether or not to repeat reading the original on the document table, reading the original on the ADF 100, and reading the original multiple times in combination. FALSE” (initialize). Note that the value of the continuous reading flag is stored in the RAM 406. After executing the process in S1102, the CPU 401 advances the process to S1200.
In S1103, the CPU 401 sets the value of the continuous reading flag to "TRUE" and advances the process to S1200. Note that details of the process in S1200 will be described later using FIG. 12.

Subsequently, in S704 of FIG. 7, the CPU 401 refers to the value of the scan end flag stored in the RAM 406 and determines whether the value of the scan end flag is "TRUE". If the CPU 401 determines in S704 that the result is "TRUE" (YES), the CPU 401 advances the process to S705. On the other hand, if the CPU 401 determines NO in S7046, it advances the process to S706.

The CPU 401 reads the image data of the original S stored in the HDD 409 in S1219 and S1224, which will be described later, and temporarily stores it in the RAM 406. Thereafter, the CPU 401 instructs the image forming unit 500 to perform printing processing based on the image data of the document S temporarily stored in the RAM 406 (S705).

After executing the process in S705, the CPU 401 advances the process to S706. In S706, the CPU 401 deletes the image data of the document S stored in the HDD 409 in S1219 and S1224, which will be described later, and ends the series of processes related to FIG. The details of the series of processes for receiving a copy job execution instruction and executing the received copy job have been described above.

[Series of processes related to scanning]
FIG. 12 is a flowchart illustrating a method of controlling the image reading device according to this embodiment. This example corresponds to the detailed procedure of a series of processes (S1200) related to scanning by the CPU 401. Note that the processing shown in each step is realized by the CPU 401 of the controller unit 400 executing the control program read from the ROM 407 and developed in the RAM 406.

In S1201, the CPU 401 determines whether the document S is placed on the document tray 30. If the CPU 401 determines that the document S is placed on the document tray 30 (YES in S1201), the process proceeds to S1202. On the other hand, if the CPU 401 determines NO in S1201, the process advances to S1222.

In S1202, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to transport the original S placed on the original tray 30. After executing the process in S1202, the CPU 401 advances the process to S1203. In S1203, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to detect whether there is any abnormality in the shape of the document S conveyed in S1202. The control unit (CPU 321) of the image reading unit 200 detects an abnormality in the shape of the document, and notifies the CPU 401 of the detection result (S1203).

After executing the process in S1203, the CPU 401 advances the process to S1204. If the CPU 401 receives a shape abnormality (YES in S1204), the CPU 401 advances the process to S1205. On the other hand, if the CPU 401 determines NO in S1204, the process advances to S1212.

In S1205, the CPU 401 refers to the setting information stored in the RAM 406 and determines whether the bound original detection mode is enabled. If the CPU 401 determines that the bound document detection mode is valid (YES in S1205), the process proceeds to S1206. On the other hand, if the CPU 401 determines in S1205 that it is invalid, the CPU 401 advances the process to S1212.

In S1206, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to interrupt conveyance of the original. Along with the interruption of scanning, the conveyance of the original S and the reading of the image of the original S are stopped.

After executing the process in S1206, the CPU 401 advances the process to S1207. In S1207, CPU 401 displays notification screen 1300 shown in FIG. 13 on LCD touch panel 600. Note that the notification screen 1300 shown in FIG. 13 is a screen for prompting the user to place the document S on the document tray 30 again. Further, the notification screen 1300 is a screen for confirming to the user that if an abnormality in the shape of the document S is detected, the user wants to continue scanning by reading the document on the document table. Note that the notification screen 1300 is displayed as a screen that accepts a switching instruction to switch from the first reading process in which the ADF 100 reads the original document conveyed to the second reading process in which the original document placed on the document table is continuously read. .

After executing the process in S1207, the CPU 401 advances the process to S1208. In step S1208, the CPU 401 determines whether an instruction to cancel the scan has been received. For example, the CPU 401 determines that an instruction to cancel the scan has been received in response to the user pressing the cancel button 1301 on the notification screen 1300. If the CPU 401 determines that the instruction to cancel the scan has been received (YES in S1208), the CPU 401 ends the series of processes (S1200) in FIG. 12 and advances the process to S704 in FIG. 11. On the other hand, if the CPU 401 determines NO in S1208, the process advances to S1209.

In S1209, the CPU 401 determines whether a scan restart instruction has been received. For example, the CPU 401 determines that the scan restart instruction has been received in response to the start key 607 on the operation unit 405 being pressed by the user.

If the CPU 401 determines that the scan restart instruction has been received (YES in S1209), the process advances to S1210. On the other hand, if the CPU 401 determines NO in S1209, the process returns to S1208.

In S1210, the CPU 401 determines whether the button 1302 for reading on the document table on the notification screen 1300 shown in FIG. 13 has been pressed. If the CPU 401 determines that the button 1302 for reading on the document table is pressed (YES in S1210), the process advances to S1211. On the other hand, if the CPU 401 determines NO in S1210, the process returns to S1201.
In S1211, the CPU 401 overwrites the value of the continuous reading flag stored in the RAM 406 as "TRUE", and returns the process to S1201.

In S1212, the CPU 401 determines whether a paper jam has occurred in the ADF 100. For example, the CPU 321 of the image reading unit 200 determines that a jam has occurred if the separation sensor 24 cannot detect the document even after a certain period of time (t1) has passed since the start of conveyance.
Then, the CPU 321 notifies the CPU 401 of the controller section 400 of the jam occurrence. The CPU 401, which has been notified of the occurrence of a paper jam, determines that a paper jam has occurred. If the CPU 401 determines that a paper jam has occurred in the ADF 100 (YES in S1212), the process proceeds to S1213. On the other hand, if the CPU 401 determines NO in S1212, it advances the process to S1218.

In S1213, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to interrupt conveyance of the original. Along with the interruption of scanning, the conveyance of the original S and the reading of the image of the original S are stopped.

After executing the process in S1213, the CPU 401 advances the process to S1214. In S1214, the CPU 401 determines whether the paper jam that occurred in the ADF 100 has been cleared. For example, the CPU 321 of the image reading unit 200 checks the values of the various sensors 304 notified from the CPU 300 of the ADF 100, and determines that the jam has been cleared if the document S is not detected after the separation sensor 24 (downstream).
Then, the CPU 321 notifies the CPU 401 of the controller section 400 that the jam has been cleared. The CPU 401, which has been notified of the paper jam, determines that the paper jam has been cleared. If the CPU 401 determines that the paper jam has been cleared in the ADF 100 (YES in S1214), the process proceeds to S1215. On the other hand, if the CPU 401 determines NO in S1214, it repeats the process shown in S1214.

In S1215, CPU 401 displays notification screen 1400 shown in FIG. 14 on LCD touch panel 600. Note that the notification screen 1400 shown in FIG. 14 is a screen for prompting the user to place the document S on the document tray 30 again.

After executing the process in S1215, the CPU 401 advances the process to S1216. In S1216, the CPU 401 determines whether an instruction to cancel the scan has been received. For example, the CPU 401 determines that an instruction to cancel the scan has been received in response to the user pressing the cancel button 1402 on the notification screen 1400. If the CPU 401 determines that the instruction to cancel the scan has been received (YES in S1216), the CPU 401 ends the series of processes (S1200) related to FIG. 12 and advances the process to S704 in FIG. 11. On the other hand, if the CPU 401 determines NO in S1216, the process advances to S1217.

In S1217, the CPU 401 determines whether a scan restart instruction has been received. For example, the CPU 401 determines that the scan restart instruction has been received in response to the start key 607 on the operation unit 405 being pressed by the user.

If the CPU 401 determines that the scan restart instruction has been received (YES in S1217), the process returns to S1201. On the other hand, if the CPU 401 determines NO in S1217, the process returns to S1216.
In S1218, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to read the image of the transported document S.

After executing the process in S1218, the CPU 401 advances the process to S1219. The CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to transfer the read image data to the controller unit 400. Then, the CPU 401 stores the image data of the document S transferred to the controller unit 400 in the HDD 409 (S1219).

After executing the process in S1219, the CPU 401 advances the process to S1220. The CPU 401 determines whether the document S is placed on the document tray 30 or not. If the CPU 401 determines that the document S is placed on the document tray 30 (YES in S1220), the process proceeds to S1202. On the other hand, if the CPU 401 determines NO in S1220, the process proceeds to S1221.

In S1221, the CPU 401 determines whether the value of the continuous reading flag is "TRUE". If the value of the continuous reading flag is "TRUE" (YES in S1221), the CPU 401 advances the process to S1225. On the other hand, if the CPU 401 determines NO in S1221, the process advances to S1229.

In S1222, the CPU 401 determines whether the value of the continuous reading flag is "TRUE". If the value of the continuous reading flag is "TRUE" (YES in S1222), the CPU 401 advances the process to S1223. On the other hand, if the CPU 401 determines NO in S1222, the process returns to S1201. In S1223, the CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to read the image of the document S on the document table.

After executing the process in S1223, the CPU 401 advances the process to S1224. The CPU 401 instructs the control unit (CPU 321) of the image reading unit 200 to transfer the read image data to the controller unit 400. Then, the CPU 401 stores the image data of the document S transferred to the controller unit 400 in the HDD 409 (S1224).

After executing the process in S1224, the CPU 401 advances the process to S1225. In S1225, CPU 401 displays notification screen 1400 shown in FIG. 14 on LCD touch panel 600. Note that the notification screen 1400 shown in FIG. 14 is a screen for allowing the user to select whether or not to read the next document.

After executing the process in S1225, the CPU 401 advances the process to S1226. In S1226, the CPU 401 determines whether an instruction to cancel the scan has been received. For example, the CPU 401 determines that an instruction to cancel the scan has been received in response to the user pressing the cancel button 1402 on the notification screen 1400. If the CPU 401 determines that the instruction to cancel the scan has been received (YES in S1226), the CPU 401 ends the series of processes (S1200) related to FIG. 12 and proceeds to S704 in FIG. 11. On the other hand, if the CPU 401 determines NO in S1226, the process advances to S1227.

In S1227, the CPU 401 determines whether an instruction to read the next document has been received. For example, the CPU 401 determines that the scan restart instruction has been received in response to the start key 607 on the operation unit 405 being pressed by the user.

If the CPU 401 determines that the instruction to read the next document has been accepted (YES in S1227), the CPU 401 returns the S process to 1201. On the other hand, if the CPU 401 determines NO in S1227, it advances the process to S1228.

In S1228, the CPU 401 determines whether or not the end of the scan has been accepted. For example, the CPU 401 determines that the instruction to end the scan has been received in response to the user pressing the cancel button 1101 on the notification screen 1100.

If the CPU 401 determines that the instruction to end the scan has been received (YES in S1228), the process advances to S1229. On the other hand, if the CPU 401 determines NO in S1228, the process returns to S1226.

In S1229, the CPU 401 overwrites the value of the scan end flag stored in the RAM 406 as "TRUE". After executing the process of S1227, the CPU 401 ends the series of processes (S1200) related to FIG. 12, and proceeds to S704 of FIG. 11. The above is the details of the series of processes related to scanning (S1200).
According to the second embodiment, it is possible to present the cause of job interruption to the user and leave it to the user's choice whether to instruct the user to switch the recovery process to manual continuous reading process.
In other words, if the shape of the transported document is not normal due to binding such as stapling, the cause should be presented and the user can receive instructions to read the documents placed on the document table continuously. Can be done.

The present invention supplies a program that implements one or more functions of the embodiments described above to a system or device via a network or a storage medium. It can also be realized by a process in which one or more processors in the computer of the system or device read and execute the program. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions. Specifically, this can be realized by a control circuit (ASIC) designed to execute processes based on each flowchart to execute processes by the CPU 300, CPU 321, and CPU 401.

100ADF
200 Image reading section
400 Controller section
405 Operation section
500 Image forming section

Claims (17)

a display means;
a conveying means for conveying the original;
reading means for reading an image of the document conveyed by the conveyance means;
a detection means for detecting an abnormality in the shape of the document being conveyed by the conveyance means ;
On the condition that the detecting means detects an abnormality in the shape of the document being transported , the display means is configured to be a reception unit that receives an instruction to disable a function for detecting an abnormality in the shape of the document being transported. An image processing device characterized by performing display. 2. The display device according to claim 1, wherein the display device further displays a message prompting an operation on the document on the condition that the detection device detects an abnormality in the shape of the document being transported . Image processing device. further comprising a document tray;
The conveying means conveys the original placed on the original tray,
The display means further displays a display prompting an operation to return the original to the first sheet and place the original on the original tray, on the condition that the detection means detects an abnormality in the shape of the original being transported . The image processing apparatus according to claim 2, further comprising: a. The display means further displays a message for disabling a function for detecting an abnormality in the shape of the document being conveyed , on the condition that the detection means detects an abnormality in the shape of the document being conveyed . The image processing apparatus according to any one of claims 1 to 3, characterized in that: further comprising a sensor;
The image processing apparatus according to any one of claims 1 to 4, wherein the detection means detects , with the sensor , an abnormality in the shape of the document being conveyed by the conveyance means. The image processing apparatus according to any one of claims 1 to 5, further comprising another detection means for detecting a jam of a document conveyed by the conveyance means. 7. The conveyance means interrupts conveyance of the document being conveyed on the condition that the detection means detects an abnormality in the shape of the document being conveyed . The image processing device described in . The image reading device according to any one of claims 1 to 7, further comprising printing means for printing the image of the document read by the reading means. a conveying means for conveying the original;
A method for controlling an image processing apparatus, comprising: a reading means for reading an image of the document conveyed by the conveying means,
a detection step of detecting an abnormality in the shape of the document being transported by the transporting means ;
a display step of displaying a reception unit that accepts an instruction to disable a function for detecting an abnormality in the shape of the document being transported , on the condition that an abnormality in the shape of the document being transported is detected in the detection step; A method for controlling an image processing device, comprising: 10. The displaying step further includes displaying a prompt to operate the document on the condition that an abnormality in the shape of the document being transported is detected in the detection step. A method for controlling an image processing device. further comprising a document tray;
The conveying means conveys the original placed on the original tray,
The display step further displays a display prompting an operation to return the document to the first sheet and place the document on the document tray, on the condition that an abnormality in the shape of the document being conveyed is detected in the detection step. 11. The method of controlling an image processing apparatus according to claim 10, further comprising the step of: controlling the image processing apparatus; The display step further displays a message for disabling a function for detecting an abnormality in the shape of the document being transported , on the condition that an abnormality in the shape of the document being transported is detected in the detection step. 12. The method for controlling an image processing apparatus according to claim 9, characterized in that: further comprising a sensor;
The image processing apparatus according to any one of claims 9 to 12, wherein the detecting step includes detecting , by the sensor , an abnormality in the shape of the document being transported by the transporting means. Control method. 14. The method of controlling an image processing apparatus according to claim 9, further comprising another detection step of detecting a jam of a document transported by the transporting means. 15. Any one of claims 9 to 14, characterized in that, on the condition that an abnormality in the shape of the document being conveyed is detected in the detection step, the conveyance means interrupts conveyance of the document being conveyed. A method for controlling an image processing device according to . 16. The method of controlling an image reading apparatus according to claim 9, further comprising a printing step of printing an image of the document read by the reading means. A program for causing a computer to execute the method for controlling an image processing apparatus according to claim 9.

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