JP2013028141A - Image forming apparatus, information processing method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reproduce processing in the image forming apparatus in same job order and event order at a certain time point.SOLUTION: The image forming apparatus includes: a job storage means which stores a job received by a receiving means in a storage device together with time information; a generation means which develops the job received by the receiving means and generates a page image; a structuring means which structures the page image generated by the generation means as the job; an image forming means which forms the job structured by the structuring means into an image; a storage means which stores an event, that occurs while the job is formed into the image by the image forming means, in the storage device together with the time information; a specifying means which specifies the job and the event by the storage device based on the input time information when the time information is input through an UI screen displayed on an operation part; and a reproducing means which executes the job and event stored in the storage device sequentially from the jobs and events specified by the specifying means.

Description

  The present invention relates to an image forming apparatus, an information processing method, and a program.

2. Description of the Related Art Conventionally, there are many cases where a user or an operator causes a plurality of jobs or procedures to be executed in a certain procedure with respect to an image forming apparatus. For example, a user or an operator prints a job for performing warm-up operation after starting the image forming apparatus every morning. After that, the image forming apparatus may be calibrated every day, and a flow such as printing a measurement chart to check a color variation and then executing a standard job may be executed by the image forming apparatus every day. Furthermore, even if the user or operator has stabilized the color of the image forming apparatus at a certain point in time, but the color has changed at the present time, There was a very high demand to return to the conditions and execute the job.
Consider not only users and operators but also managers who manage image forming apparatuses and engineers who perform maintenance. In the image forming apparatus, when a problem such as a paper jam (jam), an error, or a color variation occurs, it is necessary to simulate the operation of the image forming apparatus when the problem occurs in order to identify the cause.

For this purpose, an image forming apparatus that records an operation history of a user interface of the image forming apparatus and re-executes a plurality of jobs according to the recorded operation history procedure has been proposed.
For example, Patent Document 1 discloses a technique for reading job settings from a job history of an image forming apparatus and displaying the setting procedure on a user interface of the image forming apparatus. Japanese Patent Application Laid-Open No. 2004-228688 discloses a technique for buffering an input and a job to the user interface of the image forming apparatus and re-executing the job according to the operation procedure.

JP 2007-208440 A JP 2008-283468 A

However, the above-described conventional technology has the following problems.
In recent years, in a highly functional image forming apparatus, the context of jobs is very complicated.
FIG. 1 is a diagram illustrating an example of a time relationship between a plurality of jobs in the image forming apparatus.
First, job A is input and printing is started. During printing of job A, no paper is interrupted at 201. Thereafter, when the user or operator inputs the interrupt job B, the job A is interrupted and the job B is printed. When printing of job B is completed, the process returns to printing of job A. Next, although the job C is input, the job C is not started immediately after the end of the job A. In 202, for example, temperature adjustment and calibration of the fixing machine are executed, and the start of the job C is delayed.
In particular, the timing at which a job is interrupted depends on whether or not image formation for the corresponding page has already been performed. In the example of the interrupt job, depending on the processing load at that time and the memory capacity, it is difficult to reproduce the desired job order only by re-executing the recorded user interface operation. In another example, as for the color of the product of the image forming apparatus, the duty of the printed matter (the usage rate of the colorant such as ink and toner in one page) and how long has passed since the calibration was performed. , Etc., depending on the conditions. Furthermore, an event such as waiting for paper supply without paper or adjusting the temperature of the fixing device may also occur. In such a case, it is difficult to reproduce under the same conditions only by re-executing the recorded user interface operation.

  SUMMARY An advantage of some aspects of the invention is that the processing in the image forming apparatus is reproduced in the same job order and event order as at a certain point in time.

  Accordingly, the present invention provides an image forming apparatus having an operation unit and a storage device, a receiving unit that receives a job, and a job storage unit that stores the job received by the receiving unit in the storage device together with time information A generating unit that expands the job received by the receiving unit and generates a page image; a configuration unit that configures the page image generated by the generating unit as a job; and a job configured by the configuration unit Via an image forming means for forming an image, a storage means for saving an event generated during image formation of the job by the image forming means in the storage device together with time information, and a UI screen displayed on the operation unit When the time information is input, the specifying means for specifying a job and an event from the storage device based on the input time information, and the specifying means Sequentially from the job and events, having a reproduction means for executing the job and events are stored in the storage device.

  According to the present invention, the processing in the image forming apparatus can be reproduced in the same job order and event order as at a certain point in time.

3 is a diagram illustrating an example of a time relationship between a plurality of jobs in the image forming apparatus. FIG. 1 is a diagram illustrating an example of an image forming apparatus. 2 is a diagram illustrating an example of a controller 130 of the image forming apparatus. FIG. It is a figure which shows an example of a software module. 3 is a diagram illustrating a screen that displays a current situation among the UI screen configurations displayed on the screens of the operation unit 150 and the client computer 630 of the image forming apparatus 100. FIG. 3 is a diagram illustrating a screen that displays past history statuses among UI screen configurations displayed on the screens of an operation unit 150 and a client computer 630 of the image forming apparatus 100. FIG. 4 is a flowchart illustrating information processing by a controller 130 of the image forming apparatus 100 according to the first embodiment. 6 is a flowchart illustrating job reproduction processing by a controller 130 of the image forming apparatus 100 according to the embodiment. 6 is a flowchart illustrating a processing procedure of a job storage unit 510 and an event / parameter storage unit 550 according to the first embodiment. 4 is a flowchart illustrating a job reproduction processing procedure of a controller according to the first embodiment. 10 is a flowchart illustrating a processing procedure of a job storage unit 510 and an event / parameter storage unit 550 according to the second embodiment. 10 is a flowchart illustrating information processing by a controller 130 of the image forming apparatus 100 according to the third embodiment. 10 is a flowchart for explaining thumbnail display processing by a controller of the image forming apparatus according to the third embodiment. 10 is a flowchart illustrating information processing by a controller 130 of the image forming apparatus 100 according to the fourth embodiment. 10 is a flowchart for describing image duty calculation processing by a controller 130 of the image forming apparatus 100 according to the fourth embodiment. 10 is a flowchart for explaining full-screen halftone image generation processing by a controller 130 of the image forming apparatus 100 according to the fourth embodiment. It is a figure which shows an example of an input image. It is a figure which shows an example of a full surface halftone image. 10 is a flowchart for explaining information processing by a controller of the image forming apparatus according to the fifth embodiment. 10 is a flowchart for explaining mosaic image generation processing by a controller of the image forming apparatus according to the fifth embodiment. It is a figure which shows an example of an alternative image. FIG. 10 illustrates a configuration of an HDD 604 according to a sixth embodiment. 18 is a flowchart illustrating a processing procedure of a job storage unit 510 and an event / parameter storage unit 550 according to the sixth embodiment. 18 is a flowchart illustrating a method for saving data stored in a buffer according to the seventh embodiment. 10 is a flowchart illustrating a processing procedure of an image forming apparatus according to an eighth embodiment. 20 is a flowchart illustrating a reproduction processing procedure of the image forming apparatus according to the eighth embodiment. 20 is a flowchart illustrating a reproduction processing procedure of the image forming apparatus according to the ninth embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<< Embodiment 1 >>
<Device configuration>
FIG. 2 is a diagram illustrating an example of the image forming apparatus.
The image forming apparatus of the present embodiment will be described using an electrophotographic image forming apparatus, but this does not limit the present embodiment, and various image forming systems such as an ink jet system and offset printing are used. This is also true for the image forming apparatus used.
The image forming apparatus 100 includes a developing station 101, a fixing station 102, and a paper feed deck 109. The controller 130 is a control unit that controls each device. The operation unit 150 has both an LCD and a touch panel, and allows the user of the image forming apparatus to check the printing status and make various settings. The scanner 160 can perform a copy function by reading a document and transferring it as image information to the controller 130. In each of the developing units 104 to 107 of CMYK, an input image from the controller 130 is developed on a photosensitive drum (not shown) built in each developing unit, and the toner adheres to the developing unit and a toner image is formed on the photosensitive drum. It is formed. The developed CMYK toner images are transferred to the intermediate transfer belt 108 and then transferred to a sheet (recording medium) fed from the sheet feed deck 109. The sheet on which the toner image is transferred in this manner is sent to the fixing station 102, and heat and pressure are applied by the fixing roller 110. As a result, the toner is melted and fixed on the paper, and printing is completed.

<Controller configuration>
FIG. 3 is a diagram illustrating an example of the controller 130 of the image forming apparatus.
A central processing unit (CPU) 601 executes a program developed in the RAM 603 to control and calculate each unit in the device. The RAM 603 is used as a program storage area, a temporary storage area for various data, and a work memory. A hard disk drive (HDD) 604 is a large-capacity storage device, and various control programs executed by the CPU 601 are installed. The HDD 604 is also used as a temporary storage area for various data to be processed. When the power of the image forming apparatus is turned on, the boot program of the HDD 604 is activated, and the OS and control program installed in the HDD 604 are read out, loaded into the RAM 603, and loaded. The CPU 601 executes processing according to the program developed in the RAM 603, and executes various information processing described later. A network interface (I / F) 602 communicates with other devices such as the client computer 630 via an external network. An engine interface (I / F) 605 manages communication and control with the printer engine 608. The printer engine 608 includes a developing station 101 and a fixing station 102 shown in FIG. A scanner interface (I / F) 606 manages communication and control with the scanner 609. A system bus 607 is a bus that connects the CPU 601 and the above-described units, and transmits control signals, addresses, data, and the like.
The client computer 630 is equipped with an HDD 651 and a printer driver 650 is installed. The printer driver 650 converts the drawing command of the client computer into PDL data that can be output by the image forming apparatus 100. In addition, the printer driver 650 adds settings of various image forming apparatuses to the PDL data and transmits them to the image forming apparatus 100.

<Software module configuration>
FIG. 4 is a diagram illustrating an example of a software module.
The function of each software module is realized by the CPU 601 executing a control program expanded in the RAM 603.
The controller 130 is a module that performs main control of the image forming apparatus.
A PDL job reception unit 501 receives a print job via a network interface (I / F) 602. The PDL job development unit 502 analyzes the received print job, develops it, and passes it to the PDL interpreter 503. The PDL interpreter 503 expands PDL (page description language) data included in the print job and converts it into an intermediate data format. Here, the PDL data is, for example, PDF data.
The RIP processing unit 504 receives the converted intermediate data format data, performs RIP processing, and converts it into image data.

On the other hand, the scan job receiving unit 531 receives a scan image via a scanner interface (I / F) 606. The scan image processing unit 532 performs image processing such as RBG-CMYK conversion, color correction, and skew correction on the received scan image.
The job storage unit 510 is mounted on the RAM 603 or the HDD 604 and has a buffer for storing jobs. The job storage unit 510 is connected to the PDL job reception unit 501, the RIP processing unit 504, the scan job reception unit 531, and the scan image processing unit 532. The job storage unit 510 stores the received PDL job, the image data subjected to RIP processing, the received scan image, and the scan image subjected to image processing.
A page processing unit 505 performs imposition processing of the received image data. The job transmission unit 506 transmits the image data generated in this way to the printer engine control unit 540.
The event / parameter storage unit 550 is mounted on the RAM 603 or the HDD 604 and connected to the software modules. The event parameter storage unit 550 sequentially stores the event parameters of each module.

<UI screen configuration>
FIG. 5 is a diagram illustrating a screen that displays the current status among the UI screen configurations displayed on the screens of the operation unit 150 and the client computer 630 of the image forming apparatus 100.
In order from the top, the submitted jobs and their printing status are displayed as bar graphs. The marker 302 represents the current time, and the bar graph on the marker represents the job currently being processed. On the left side of the marker 302 is a past history, and when an interruption event such as paper out occurs as indicated by 303 in the figure, the event is also displayed. On the other hand, the right side of the marker 302 represents future prediction. Events that have already been scheduled are displayed, but events such as the aforementioned no paper are not displayed.
The UI screen 301 can be scrolled to the left and right. When the UI screen 301 is scrolled to the right, the past history status is displayed.

FIG. 6 is a diagram illustrating a screen that displays past history statuses among the UI screen configurations displayed on the screens of the operation unit 150 and the client computer 630 of the image forming apparatus 100.
The playback marker 401 is displayed only on the history screen and can be scrolled left and right on the screen. Job thumbnails and page numbers 402 are displayed for jobs that intersect the playback marker. The user moves the playback marker, selects a desired point in time, and presses the playback button. The image forming apparatus 100 starts reproducing the job from the selected time point.

<Printing Flow of Embodiment 1>
Next, control of the image forming apparatus 100 according to the first embodiment will be described.
FIG. 7 is a flowchart illustrating information processing by the controller 130 of the image forming apparatus 100 according to the first embodiment. The program for executing this process is expanded in the RAM 603 as described above, and the process shown in this flowchart is executed by the CPU 601 executing this control program.
In step S700, processing by the controller 130 is started. In step S701, the PDL job reception unit 501 or the scan job reception unit 531 receives a job via the network I / F 602 or the scanner interface (I / F) 606. In step S702, the controller 130 determines whether the input job is a PDL job or a scan job. If it is determined that the job is a PDL job, in step S705, the job storage unit 510 stores the received PDL job in a buffer together with time information. In step S706, the PDL job development unit 502 develops a PDL job. In step S707, the PDL interpreter 503 generates intermediate data from the PDL.
In step S708, the RIP processing unit 504 performs RIP processing on the generated intermediate data to generate a page image.
In step S711, the job storage unit 510 stores the generated RIP-completed page image together with time information in a buffer (page image storage).

If it is determined in step S702 that the input job is a scan job, in step S723, the job storage unit 510 stores the received scan job in a buffer together with time information.
In step S724, the scan image processing unit 532 performs image processing such as RGB-CMYK conversion, color correction, and skew correction on the received scan image.
In step S727, the job storage unit 510 stores the image-processed scanned image in a buffer together with time information.
In step S731, the page processing unit 505 performs page processing such as imposition.
In step S734, the job storage unit 510 stores the page processed image in the buffer together with time information.
In step S735, the job transmission unit 506 transmits the page processed image to the printer engine control unit 540.
In step S736, the event parameter storage unit 550 stores the event parameter in the printer engine 608 together with the time information. Here, the event is, for example, an event such as no paper, a paper jam (jam), or calibration, and the parameters are, for example, parameters such as toner density, tone curve, and engine state.
In step S737, the printer engine control unit 540 prints the job received by the printer engine.
In step S <b> 738, the controller 130 determines whether a job reproduction instruction has been issued via the UI screen 301. If there is no reproduction instruction, the process returns to step S701 to receive a new job.
If it is determined in step S738 that a job reproduction instruction has been issued, the process proceeds to the next flow in step S799.

FIG. 8 is a flowchart for explaining job reproduction processing by the controller 130 of the image forming apparatus 100 according to the embodiment.
In step S801, the controller 130 receives the input of the playback marker 401 and specifies the playback start time.
In step S802, the controller 130 searches the buffer of the job storage unit 510. In step S803, the controller 130 determines whether a job corresponding to the specified reproduction start time remains and can be reproduced. If it is determined that reproduction is not possible, the controller 130 displays an error message on the UI screen 301 in step S810 and ends the process.
If it is determined in step S803 that a job corresponding to the specified reproduction start time remains and can be reproduced, the controller 130 refers to the job storage unit 510 or the event / parameter storage unit 550 in step S821. In step S822, the controller 130 specifies a job to start reproduction from the referred event parameter job and the specified reproduction start time.
In step S823, the controller 130 specifies a playback start page from the specified job and the specified playback start time.

In step S824, the controller 130 uses the identified reproduction start job to start job reproduction sequentially from the identified reproduction start page. At this time, the controller 130 specifies the RIP-completed image saved in S711 of FIG. 7 from the specified playback start time, and uses it for job playback. More specifically, the controller 130 performs image formation or the like using the RIP-finished image specified in job reproduction.
In step S825, the controller 130 determines whether an end event has been notified via the UI screen 301. If an end event has been notified, the controller 130 ends the process in step S899.
If the end event is not notified in step S825, in step S826, the controller 130 determines whether the job is the last recorded job. If it is determined that the job is the final job, the controller 130 ends the process in step S899.
If it is determined in step S826 that the job is the final job, the process proceeds to step S830, and the controller 130 specifies the next stored job, and reproduces the specified job in step S824.

Here, the processing flow of the job storage unit 510 and the event / parameter storage unit 550 according to steps S705, S711, S723, S727, S734, and S736 will be described in detail.
FIG. 9 is a flowchart illustrating processing procedures of the job storage unit 510 and the event / parameter storage unit 550 according to the first embodiment.
Starting in step S900, in step S901, the size of the data received by the job storage unit 510 and the event / parameter storage unit 550 is confirmed. In step S902, the buffer capacity of the job storage unit 510 and the event / parameter storage unit 550 is confirmed. In step S903, the job storage unit 510 and the event / parameter storage unit 550 determine whether the capacity of the confirmed buffer can store the confirmed received data size. If it is determined that the data cannot be stored in the buffer, the job storage unit 510 and the event / parameter storage unit 550 shift to step S904. Then, the job storage unit 510 and the event parameter storage unit 550 delete old data in time series from the data stored in the buffer until the received data size is entered, and the process proceeds to step S905.
If it is determined in step S903 that the data can be stored in the buffer, the job storage unit 510 and the event / parameter storage unit 550 shift to step S905.
In step S905, the job storage unit 510 and the event / parameter storage unit 550 store the received data together with the time information in the buffer, and the process ends.

Next, the processing flow of the controller 130 in step S824 will be described in detail.
FIG. 10 is a flowchart illustrating a job reproduction processing procedure of the controller 130 according to the first embodiment.
In step S1001, the controller 130 receives a job input. In step S <b> 1002, the controller 130 sets parameters stored in the event / parameter storage unit 550 to the printer engine control unit 540.
In step S1003, the controller 130 determines an event that occurs during job execution from the event / parameter storage unit 550 and sets the time.
In step S1004, the controller 130 starts job execution from the start page identified in step S823.
In step S1005, the controller 130 determines whether or not the set event time has been reached. If it is determined that the event time has been reached, in step S1006, the controller 130 causes the printer engine control unit 540 to reproduce the event, and the process proceeds to step S1007.
If it is determined in step S1005 that there is no event time, in step S1007, the controller 130 continues printing until the end of the job.
By controlling printing as described above, all jobs can be received, jobs, events, and parameters can be stored, and processing in the image forming apparatus can be reproduced according to the stored job procedure.

<< Embodiment 2 >>
In the first embodiment, the method of uniformly discarding old data when the buffer is full has been described. In the second embodiment, a method of discarding old data from a large amount of data will be described.
In the second embodiment, the information processing by the controller 130 of the image forming apparatus 100 is the same information processing as the flowcharts described in FIGS. 7 and 8 in the first embodiment.
Among these, the processing flow of the job storage unit 510 and the event / parameter storage unit 550 in steps S705, S711, S723, S727, S734, and S736 according to the second embodiment will be described in detail.
In general, an image after RIP processing has a larger data amount than a received PDL job. Regarding the scanned image, there is no significant difference in the data amount between the received scanned image and the scanned image subjected to image processing. On the other hand, the amount of data of events and parameters is relatively small for these PDL data, RIP-processed images, and scanned images.

FIG. 11 is a flowchart illustrating processing procedures of the job storage unit 510 and the event / parameter storage unit 550 according to the second embodiment.
Starting in step S900, in step S901, the size of the data received by the job storage unit 510 and the event / parameter storage unit 550 is confirmed. In step S902, the buffer capacity of the job storage unit 510 and the event / parameter storage unit 550 is confirmed. In step S903, the job storage unit 510 and the event / parameter storage unit 550 determine whether the capacity of the confirmed buffer can store the size of the confirmed received data. If it is determined that the data can be stored in the buffer, the job storage unit 510 and the event / parameter storage unit 550 store the received data together with the time information in the buffer in step S905, and the process ends.
If it is determined in step S903 that the received data size cannot be stored, the job storage unit 510 and the event / parameter storage unit 550 shift to step S1101. In step S <b> 1101, the job storage unit 510 and the event / parameter storage unit 550 delete old data in chronological order from the RIPed image data stored in the buffer of the job storage unit 510.

In step S1102, the job storage unit 510 and the event / parameter storage unit 550 determine whether or not the confirmed buffer capacity can store the confirmed received data size. If it is determined that the data can be stored, in step S905, the job storage unit 510 and the event / parameter storage unit 550 store the received data in the buffer together with the time information, and the process ends. If it is determined in step S1102 that the data cannot be stored, the job storage unit 510 and the event / parameter storage unit 550 shift to step S1103. In step S <b> 1103, the job storage unit 510 and the event / parameter storage unit 550 delete old data in time series from the scanned image data processed in the image stored in the buffer of the job storage unit 510.
In step S1104, the job storage unit 510 and the event / parameter storage unit 550 determine whether the capacity of the confirmed buffer can store the confirmed received data size. If it is determined that the data can be stored, in step S905, the job storage unit 510 and the event / parameter storage unit 550 store the received data in the buffer together with the time information, and the process ends. If it is determined in step S1104 that the data cannot be stored, the process proceeds to step S1105, and the job storage unit 510 and the event / parameter storage unit 550 perform time series out of the PDL data stored in the buffer of the job storage unit 510. Old data is deleted.

In step S1106, the job storage unit 510 and the event / parameter storage unit 550 determine whether the confirmed buffer capacity can store the confirmed received data size. If it is determined that the data can be stored, in step S905, the job storage unit 510 and the event / parameter storage unit 550 store the received data in the buffer together with the time information, and the process ends. If it is determined in step S1106 that the image cannot be stored, the process proceeds to step S1107, and the job storage unit 510 and the event / parameter storage unit 550 include the received scan image data stored in the buffer of the job storage unit 510. Delete old data in series.
In step S1108, the job storage unit 510 and the event / parameter storage unit 550 determine whether the capacity of the confirmed buffer can store the confirmed received data size. If it is determined that the data can be stored, in step S905, the job storage unit 510 and the event / parameter storage unit 550 store the received data in the buffer together with the time information, and the process ends. If it is determined in step S1108 that the data cannot be stored, the job storage unit 510 and the event / parameter storage unit 550 shift to step S1109. In step S1109, the job storage unit 510 and the event parameter storage unit 550 delete old data in time series from the event parameters stored in the buffer of the event parameter storage unit 550, and the process proceeds to step S905. To do.

In step S905, the job storage unit 510 and the event / parameter storage unit 550 store the received data together with the time information in the buffer, and the process ends.
By controlling printing as described above, all jobs can be received, jobs, events, and parameters can be stored, and the processing of the image forming apparatus can be reproduced according to the stored job procedure. Further, by discarding the buffer with the largest amount of data, it becomes possible to store event parameters for a longer time, and the time that can be traced back is greatly improved. This further improves user convenience.

<< Embodiment 3 >>
In the first and second embodiments, the method of storing the post-RIP image in the job storage unit 510 has been described. In the third embodiment, a process of creating and saving a thumbnail image together with the RIP image and displaying it on the UI screen displayed on the operation unit 150 for selecting the reproduction time will be described.
FIG. 12 is a flowchart illustrating information processing by the controller 130 of the image forming apparatus 100 according to the third embodiment.
In step S700, the processing by the controller 130 is started, and the same flow as in the first embodiment is performed until reaching steps S711 and S727. In step S2401, the controller 130 generates a thumbnail image by performing resolution conversion processing on the generated post-RIP image or processed scan image (thumbnail image generation). In step S2402, the controller 130 stores the generated thumbnail image together with the time information in the job storage unit 510 (thumbnail image storage). After shifting to S731, the same flow as in the first embodiment is performed.

Next, a flow for displaying the generated thumbnail image on the UI screen will be described in detail.
FIG. 13 is a flowchart for explaining thumbnail display processing by the controller 130 of the image forming apparatus 100 according to the third embodiment.
Starting in step S2500, in step S2501, the UI screen (or the controller 130 via the UI screen) detects the movement of the reproduction marker 401 due to the user input. In step S2502, the controller 130 acquires time information on the playback marker from the UI screen. In step S2503, the controller 130 acquires a thumbnail image corresponding to the acquired time information from the job storage unit 510. In step S2504, the controller 130 displays the acquired thumbnail image on the UI screen according to the time axis.
By controlling as described above, the user can set the playback start time while confirming the thumbnail image of the job to be played back on the UI screen, and convenience is improved.

<< Embodiment 4 >>
In the second embodiment, the technique of discarding data with a large amount of data when the buffer is full has been described. However, PDL data and input image data often contain confidential information such as personal information. If it can be stored and played back later, a third party will Information can be viewed, which can be a security problem. On the other hand, when replaying a job in a case where it depends on the duty of the job (the usage rate of colorant such as ink or toner in one page), such as color variation in the image forming apparatus, It is necessary to reproduce the print contents to some extent.
In the fourth embodiment, a technique for reproducing a job by generating a substitute image without storing PDL data or image data will be described.

FIG. 14 is a flowchart illustrating information processing by the controller 130 of the image forming apparatus 100 according to the fourth embodiment.
In step S700, processing by the controller 130 is started. In step S701, the PDL job reception unit 501 or the scan job reception unit 531 receives a job via the network I / F 602 or the scanner interface (I / F) 606. In step S702, the controller 130 determines whether the input job is a PDL job or a scan job. If it is determined that the job is a PDL job, in step S706, the PDL job development unit 502 develops the PDL job. In step S707, the PDL interpreter 503 generates intermediate data from the PDL. In step S708, the RIP processing unit 504 performs RIP processing on the generated intermediate data to generate a page image.
If it is determined in step S702 that the input job is a scan job, in step S724, the scan image processing unit 532 performs image processing such as color correction and skew correction on the received scan image. .

In step S1201, the controller 130 calculates an image duty for the received post-RIP image or the scanned image after image processing. In step S1202, the job storage unit 510 stores the calculated image duty value in a buffer together with time information (average value storage).
In step S731, the page processing unit 505 performs page processing such as imposition.
In step S735, the job transmission unit 506 transmits the page processed image to the printer engine control unit 540.
In step S 736, the event / parameter storage unit 550 stores the event / parameter in the printer engine 608.
In step S737, the printer engine control unit 540 prints the job received by the printer engine.
In step S <b> 738, the controller 130 determines whether a job reproduction instruction has been issued via the UI screen 301. If there is no reproduction instruction, the process returns to step S701 to receive a new job.
If it is determined in step S738 that a job reproduction instruction has been issued, the controller 130 proceeds to the next flow in step S799.

Here, the image duty calculation flow of the controller 130 in step S1201 will be described in detail.
FIG. 15 is a flowchart for describing image duty calculation processing by the controller 130 of the image forming apparatus 100 according to the fourth embodiment.
Beginning in step S1300, in step S1301, the controller 130 receives an input of a post-RIP image or a scanned image after image processing. In step S1302, the controller 130 generates an image separated into CMYK plates for the input image.
In step S1303, the controller 130 determines the total number of pixels constituting the CMYK separated image. In step S1304, the controller 130 calculates the sum of the signal values of the pixels constituting the image, divides the sum by the total number of pixels, and calculates an average value.
In step S1305, the controller 130 repeats steps S1303 and S1304 for each of the CMYK plates and ends.

For the job reproduction process, the same flow as that described in FIG. 8 in the first embodiment can be applied. Here, the job reproduction processing in step S824 will be described in detail.
FIG. 16 is a flowchart for explaining full-screen halftone image generation processing by the controller 130 of the image forming apparatus 100 according to the fourth embodiment.
In step S1400, the controller 130 receives a job duty value from the job storage unit 510 in step S1401. In step S1402, the controller 130 receives an input of the image size. In step S1403, the controller 130 generates an image using the duty value as a signal value (page image generation). In step S <b> 1404, the controller 130 transmits the generated image to the printer engine control unit 540 via the job transmission unit 506, and performs printing using the printer engine 608.
FIG. 17A is a diagram illustrating an example of an input image. FIG. 17B is a diagram illustrating an example of a full face halftone image. The full-surface halftone image is an example of a page image that is completely filled.
According to the fourth embodiment, assuming that FIG. 17A is an input image, an entire halftone image as shown in FIG. 17B is generated and printed.
By controlling printing as described above, a job with the same duty can be reproduced even when the job contents cannot be stored and printed. Furthermore, since there is no need to store PDL jobs and image data, it is possible to store event parameters for a longer time, and the time that can be traced back is greatly improved. As a result, the image forming apparatus can be reproduced without threatening the user's security, and the convenience for the user is improved.

<< Embodiment 5 >>
In the fourth embodiment, a process for reproducing a job with the same duty even when the job contents cannot be stored and printed by printing a full-tone halftone image according to the job duty has been described. However, even when the job contents cannot be stored / printed, there may be a change in color due to the distribution of signal values on the paper. In this case, it was not possible to simulate the entire halftone image described above.
In the fifth embodiment, a technique for generating, storing, and printing a mosaic image instead of a full-tone halftone image will be described.

FIG. 18 is a flowchart illustrating information processing by the controller 130 of the image forming apparatus 100 according to the fifth embodiment.
In step S700, processing by the controller 130 is started. In step S701, the PDL job reception unit 501 or the scan job reception unit 531 receives a job via the network I / F 602 or the scanner interface (I / F) 606. In step S702, the controller 130 determines whether the input job is a PDL job or a scan job. If it is determined that the job is a PDL job, in step S706, the PDL job development unit 502 develops the PDL job. In step S707, the PDL interpreter 503 generates intermediate data from the PDL.
In step S708, the RIP processing unit 504 performs RIP processing on the generated intermediate data to generate a page image.
If it is determined in step S702 that the input job is a scan job, in step S724, the scan image processing unit 532 performs image processing such as color correction and skew correction on the received scan image. .

In step S1601, the controller 130 generates a mosaic image from the received post-RIP image or scanned image after image processing (mosaic image generation). In step S1602, the job storage unit 510 stores the generated mosaic image in a buffer together with time information (mosaic image storage).
In step S731, the page processing unit 505 performs page processing such as imposition.
In step S735, the job transmission unit 506 transmits the page processed image to the printer engine control unit 540.
In step S736, the event parameter storage unit 550 stores the event parameter in the printer engine 608 together with the time information.
In step S737, the printer engine control unit 540 prints the job received by the printer engine.
In step S <b> 738, the controller 130 determines whether a job reproduction instruction has been issued via the UI screen 301. If there is no reproduction instruction, the process returns to step S701 to receive a new job.
If it is determined in step S738 that a job reproduction instruction has been issued, the controller 130 proceeds to the next flow in step S799.

Here, the mosaic image generation flow of the controller 130 in step S1601 will be described in detail.
FIG. 19 is a flowchart for explaining mosaic image generation processing by the controller 130 of the image forming apparatus 100 according to the fifth embodiment.
Starting in step S1700, in step S1701, the controller 130 receives an input of a post-RIP image or a scanned image after image processing. In step S <b> 1702, the controller 130 generates an image separated into CMYK plates for the input image. In step S <b> 1703, the controller 130 divides the CMYK separated image with a grid having a predetermined number of vertical and horizontal pixels. Here, the size of the grid can be set via the UI screen 301, and is specified as, for example, 100 pixels vertically and horizontally. The larger the grid size, the more difficult the image is identified.
In step S1704, the controller 130 calculates an average value for all the pixels in the grid for each of the divided grids. In step S1706, the controller 130 fills the pixels in the divided grid with the calculated average value. The controller 130 applies this process to all grids. In step S1705, the controller 130 generates a mosaic image by repeating the processing from steps S7103 to S1706 for each of the CMYK plates.

For the job reproduction process, the same flow as that described in FIG. 8 in the first embodiment can be applied. Here, in step S824, the controller 130 prints the generated mosaic image.
FIG. 20 is a diagram illustrating an example of a substitute image.
According to the fifth embodiment, assuming that FIG. 17A is an input image, a mosaic image as shown in FIG. 20 is generated and printed.
By controlling printing as described above, it is possible to reproduce the image forming apparatus using the mosaic image even when the job contents cannot be stored and printed. Furthermore, since a relatively high compression can be applied to the mosaic image, the data size to be stored is reduced, the event parameter can be stored for a longer time, and the time that can be traced is greatly improved. As a result, the image forming apparatus can be reproduced without threatening the user's security, and the convenience for the user is improved.

<< Embodiment 6 >>
In the first to fifth embodiments, the job event parameters are stored in the buffer when the job is executed, and read out from the buffer and reproduced. However, the size of the buffer is limited, and when the buffer becomes full, old data is deleted. Therefore, even if playback is attempted later, the data is erased from the buffer, and playback may fail.
In the sixth embodiment, a method for saving data stored in the buffer in another area of the storage device according to a predetermined event will be described.
FIG. 21 is a diagram illustrating the configuration of the HDD 604 according to the sixth embodiment.
The HDD 604 is divided into two partitions. Each partition includes a partition 2201 for buffering jobs and event parameters, and a partition 2202 for saving job and event parameters.

FIG. 22 is a flowchart illustrating processing procedures of the job storage unit 510 and the event / parameter storage unit 550 according to the sixth embodiment.
The same flow as that of the first embodiment is followed from step S700 to step S737.
In step S1801, the job storage unit 510 and the event / parameter storage unit 550 determine whether a predetermined specific event has occurred. Here, the predetermined specific event is a paper jam or a color change. If it is determined that a specific event has not occurred, the process advances to step S738, and the job storage unit 510 and the event / parameter storage unit 550 perform normal processing.
If a specific event has occurred in step S1801, the job storage unit 510 and event / parameter storage unit 550 proceed to step S1802. In step S1802, the job storage unit 510 and the event parameter storage unit 550 copy the data stored in the buffering partition 2201 for the job and event parameters to the save partition 2202.
By controlling as described above, when an event occurs, the data stored in the buffer can be saved, and the image forming apparatus can be reproduced according to the event without clearing the buffer. The user can automatically save data in accordance with an event without worrying about buffer depletion, thereby improving user convenience.

<< Embodiment 7 >>
In the sixth embodiment, the method of saving data stored in the buffer unconditionally according to the occurrence of an event has been described. In the seventh embodiment, a method for selecting data to be saved according to the contents of an event that has occurred will be described.
In the seventh embodiment, the same flow as that in FIG. 22 in the sixth embodiment is applied. Here, a method for saving the data stored in the buffer according to the seventh embodiment will be described in detail.
FIG. 23 is a flowchart illustrating a method for saving data stored in the buffer according to the seventh embodiment.
Starting in step S1900, in step S1901, the job storage unit 510 and the event / parameter storage unit 550 receive an event input. In step S1902, the job storage unit 510 and the event / parameter storage unit 550 determine whether the input event is an event that requires the input image to be stored. If it is determined that an input image is necessary, the job storage unit 510 and the event / parameter storage unit 550 save the input image data in step S1903. If it is determined in step S1902 that an input image is not necessary, the job storage unit 510 and the event / parameter storage unit 550 directly proceed to step S1904.
In step 1904, the job storage unit 510 and the event / parameter storage unit 550 save the event / parameter described in the sixth embodiment.
By performing the control as described above, the data to be saved can be selected according to the event that has occurred, so that the saving destination data capacity can be reduced. The user can store more reproducible data, and the convenience for the user is improved.

<< Embodiment 8 >>
In the sixth and seventh embodiments, the method for saving the data stored in the buffer to the storage device included in the image forming apparatus has been described. In the eighth embodiment, a method for transmitting data stored in a buffer to a storage device on a computer connected to a network according to the occurrence of an event will be described.
FIG. 24 is a flowchart illustrating a processing procedure of the image forming apparatus according to the eighth embodiment.
The same flow as that of the first embodiment is followed from step S700 to step S737.
In step S1801, the job storage unit 510 and the event / parameter storage unit 550 determine whether a predetermined specific event has occurred. Here, the predetermined specific event is a paper jam or a color change. If it is determined that a specific event has not occurred, the job storage unit 510 and the event / parameter storage unit 550 move to step S738 and perform normal processing.
If a specific event has occurred in step S1801, the job storage unit 510 and event / parameter storage unit 550 proceed to step S2001. In step S2001, the job storage unit 510 and the event / parameter storage unit 550 transmit the data stored in the buffer to the HDD 651 on the client computer 630 connected to the network, and store the data together with the time information.

FIG. 25 is a flowchart illustrating a reproduction processing procedure of the image forming apparatus according to the eighth embodiment.
In step S801, the controller 130 receives the input of the playback marker 401 and specifies the playback start time.
In step S2201, the controller 130 downloads the saved data from the HDD 651 to a buffer included in the job storage unit 510 and the event parameter storage unit 550.
After step S802, the same processing as in the first embodiment is executed, so that the reproduction processing of the image forming apparatus can be executed as in the first embodiment.
By controlling as described above, it becomes possible to transmit the contents of the buffer to a storage device on a computer connected to the network in accordance with an event. The user can reproduce a job executed at a remote place on the familiar image forming apparatus. Furthermore, a larger capacity general-purpose storage device on the network can be used as a data storage destination, and convenience is improved.

<< Ninth Embodiment >>
In Embodiments 1 to 8, a case will be considered in which an event relating to consumables such as the absence of paper or running out of toner exists as an event to be reproduced in the reproduction processing of the image forming apparatus. For example, if there are more papers being fed than in the past time point to be reproduced, the papers actually remain in the paper feed stage when a paper out event occurs. On the other hand, if the paper being fed is less than the past time point to be played back, the paper actually does not exist in the paper feed stage before the paper out event occurs, and the image forming apparatus Accurate playback becomes difficult.
In the ninth embodiment, a control method is described in which the state of consumables such as paper and toner is determined before the image forming apparatus is reproduced, and the reproduction is possible.

FIG. 26 is a flowchart illustrating a reproduction processing procedure of the image forming apparatus according to the ninth embodiment.
In step S801, the controller 130 receives the input of the playback marker 401 and specifies the playback start time.
In step S <b> 802, the controller 130 searches the buffer of the job storage unit 510. In step S803, the controller 130 determines whether a job corresponding to the specified reproduction start time remains and can be reproduced. If it is determined that the reproduction is impossible, the controller 130 displays an error message on the UI screen 301 in step S810 and ends.
If it is determined in step S803 that a job corresponding to the specified reproduction start time remains and can be reproduced, the controller 130 refers to the job storage unit 510 or the event / parameter storage unit 550 in step S821.

In step S2301, the controller 130 refers to the job storage unit 510 or the event / parameter storage unit 550, and determines whether an event related to the consumable item occurs in the job to be reproduced. Here, if it is determined that an event related to the consumable item does not occur, the controller 130 proceeds to step S822, and thereafter performs reproduction according to the same reproduction procedure as in the first embodiment.
If it is determined in step S2301 that an event related to the consumable item occurs, the controller 130 checks the remaining amount of the consumable item in the image forming apparatus 100 in step S2302. In step S2303, the controller 130 determines whether or not the remaining amount of the consumable item is sufficient to output the job to be reproduced. That is, the controller 130 determines whether or not it is possible to process a job that starts reproduction with the remaining amount of consumables. Here, if it is determined that there is a sufficient remaining amount, the controller 130 proceeds to step S822, and thereafter performs playback in the same playback procedure as in the first embodiment.
If it is determined in step S2303 that the remaining amount of consumables is not sufficient, in step S2304, the controller 130 displays on the UI screen a prompt for replenishment of consumables with insufficient remaining amount. In step S2305, the controller 130 stands by after the display until the consumable item is replenished.
Thereafter, the controller 130 proceeds to step S822, and performs reproduction by the same reproduction procedure as in the first embodiment.

  By controlling as described above, the state of the consumables such as paper and toner is determined before the image forming apparatus is reproduced, and the reproduction process is waited until the consumables are supplied, thereby reproducing the image forming apparatus. Is possible. For the user, when the image forming apparatus notifies the set of consumables in advance, more accurate job reproduction of the image forming apparatus becomes possible.

<< Other Embodiments >>
The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, etc.) of the system or apparatus reads the program. It is a process to be executed.

As described above, according to each of the above-described embodiments, job data, job order and events, engine internal parameters, and the like are stored in a buffer. Then, using the temporarily stored job data, the order, the event, etc., the job / procedure can be executed by going back a certain time.
That is, the processing in the image forming apparatus can be reproduced in the same job order and event order as at a certain time.

  The preferred embodiments of the present invention have been described in detail above, but the present invention is not limited to such specific embodiments, and various modifications can be made within the scope of the gist of the present invention described in the claims.・ Change is possible.

Claims (18)

An image forming apparatus having an operation unit and a storage device,
A receiving means for receiving a job;
Job storage means for storing the job received by the receiving means together with time information in the storage device;
Generating means for expanding the job received by the receiving means and generating a page image;
Configuring means for configuring the page image generated by the generating means as a job;
Image forming means for forming an image of the job configured by the configuration means;
A storage unit that stores, in the storage device, an event that occurs during image formation of the job by the image forming unit;
When time information is input via the UI screen displayed on the operation unit, a specifying unit for specifying a job and an event from the storage device based on the input time information;
Reproduction means for sequentially executing jobs and events stored in the storage device from jobs and events identified by the identification means;
An image forming apparatus. Page image storage means for storing the page image generated by the generation means together with time information in the storage device;
The specifying unit specifies a job, a page image, and an event from the storage device based on the input time information,
The reproducing unit forms an image using the page image specified by the specifying unit in the image formation in the reproduction of the job specified by the specifying unit, and sequentially reproduces the job stored in the storage device. The image forming apparatus according to claim 1, wherein image formation is performed using a corresponding page image in image formation. The storage means stores the event and parameters together with time information in the storage device,
The specifying unit specifies a job, an event, and a parameter from the storage device based on the input time information,
The reproducing means reproduces the job and the event specified by the specifying means based on the parameters specified by the specifying means, and sequentially stores them in the storage apparatus based on corresponding parameters stored in the storage apparatus. The image forming apparatus according to claim 1, wherein the stored job and event are executed.   The image forming apparatus according to claim 3, wherein the parameter is a toner concentration or an engine state.   The job storage unit and the storage unit compare the free capacity of the storage device with the capacity of the data to be stored, and if the free capacity is less than the capacity of the data, the data to be stored is The old data among the data stored in the storage device is deleted based on the time information of the data stored in the storage device until there is a free space to enter. Image forming apparatus.   The image forming apparatus according to claim 5, wherein the job storage unit and the storage unit delete the old data in descending order of data amount. Thumbnail image generation means for performing resolution conversion processing on the page image generated by the generation means to generate a thumbnail image;
Thumbnail image storage means for storing the thumbnail image generated by the thumbnail image generation means in the storage device;
Display means for displaying a thumbnail image stored in the storage device according to a time axis on the UI screen;
The image forming apparatus according to claim 1, further comprising:   The storage unit determines whether a predetermined specific event has occurred after storing an event that occurred during image formation of the job by the image forming unit in the storage device together with time information; The data stored in one storage area of the storage device is saved in a storage area different from the one storage area of the storage device when it is determined that a predetermined specific event has occurred. The image forming apparatus according to any one of 1 to 7.   The storage means is a storage area different from the one storage area of the storage device among the data stored in one storage area of the storage device according to the content of the predetermined specific event. 9. The image forming apparatus according to claim 8, wherein data to be saved is selected. A confirmation means for confirming a status of the consumable when an event related to the consumable is included in the job for starting the reproduction;
A determination unit that determines whether or not the job for starting the reproduction can be processed based on the status of the consumables confirmed by the confirmation unit;
Display means for displaying a message for replenishing the consumables on the UI screen when it is determined by the determination means that the job for starting the reproduction cannot be processed;
Waiting means for waiting for reproduction of the job for starting the reproduction until the consumable is replenished after displaying the message on the display means;
The image forming apparatus according to claim 1, further comprising: An image forming apparatus having an operation unit and a storage device,
A receiving means for receiving a job;
Generating means for expanding the job received by the receiving means and generating a page image;
Average value storage means for storing the average value of the signal values of the pixels of the page image generated by the generation means together with time information in the storage device;
Configuring means for configuring the page image generated by the generating means as a job;
Image forming means for forming an image of the job configured by the configuration means;
A storage unit that stores, in the storage device, an event that occurs during image formation of the job by the image forming unit;
When time information is input via the UI screen displayed on the operation unit, an identification value that specifies an average value and an event of a pixel value of a pixel of a page image from the storage device based on the input time information Means,
Page image generation means for generating a page image that is completely filled from the average value of signal values of pixels of the page image specified by the specifying means;
Replaying means for performing replaying in sequence by forming an image of the page image generated by the page image generating means and executing an event specified by the specifying means;
An image forming apparatus. An image forming apparatus having an operation unit and a storage device,
A receiving means for receiving a job;
Generating means for expanding the job received by the receiving means and generating a page image;
Mosaic image generating means for generating a mosaic image from the page image generated by the generating means;
Mosaic image storage means for storing the mosaic image generated by the mosaic image generation means in the storage device together with time information;
Configuring means for configuring the page image generated by the generating means as a job;
Image forming means for forming an image of the job configured by the configuration means;
A storage unit that stores, in the storage device, an event that occurs during image formation of the job by the image forming unit;
When time information is input via the UI screen displayed on the operation unit, a specifying unit for specifying a mosaic image and an event from the storage device based on the input time information;
Reproduction means for performing reproduction sequentially by forming a mosaic image identified by the identification means and executing the event identified by the identification means;
An image forming apparatus. An information processing method executed by an image forming apparatus having an operation unit and a storage device,
A receiving step for receiving the job;
A job storage step of storing the job received in the reception step together with time information in the storage device;
A generation step of developing the job received in the reception step and generating a page image;
A configuration step of configuring the page image generated in the generation step as a job;
An image forming step of forming an image of the job configured in the configuration step;
A storage step of storing in the storage device together with time information an event that occurred during the image formation of the job in the image formation step;
When time information is input via the UI screen displayed on the operation unit, a specifying step of specifying a job and an event from the storage device based on the input time information;
A reproduction step of executing the job and event stored in the storage device sequentially from the job and event specified in the specifying step;
An information processing method including: An information processing method executed by an image forming apparatus having an operation unit and a storage device,
A receiving step for receiving the job;
A generation step of developing the job received in the reception step and generating a page image;
An average value storing step for storing an average value of signal values of pixels of the page image generated in the generating step in the storage device together with time information;
A configuration step of configuring the page image generated in the generation step as a job;
An image forming step of forming an image of the job configured in the configuration step;
A storage step of storing in the storage device together with time information an event that occurred during the image formation of the job in the image formation step;
When time information is input via the UI screen displayed on the operation unit, an identification value that specifies an average value and an event of a pixel value of a pixel of a page image from the storage device based on the input time information Steps,
A page image generation step of generating a page image that is completely filled from an average value of signal values of pixels of the page image specified in the specifying step;
A reproduction step of performing reproduction sequentially by forming an image of the page image generated in the page image generation step and executing the event specified in the specification step;
An information processing method including: An information processing method executed by an image forming apparatus having an operation unit and a storage device,
A receiving step for receiving the job;
A generation step of developing the job received in the reception step and generating a page image;
A mosaic image generation step of generating a mosaic image from the page image generated in the generation step;
A mosaic image storing step of storing the mosaic image generated in the mosaic image generating step together with time information in the storage device;
A configuration step of configuring the page image generated in the generation step as a job;
An image forming step of forming an image of the job configured in the configuration step;
A storage step of storing in the storage device together with time information an event that occurred during the image formation of the job in the image formation step;
When time information is input via the UI screen displayed on the operation unit, a specifying step of specifying a mosaic image and an event from the storage device based on the input time information;
A reproduction step of performing reproduction in sequence by forming an image of the mosaic image identified in the identification step and executing the event identified in the identification step;
An information processing method including: In a computer having an operation unit and a storage device,
A receiving step for receiving the job;
A job storage step of storing the job received in the reception step together with time information in the storage device;
A generation step of developing the job received in the reception step and generating a page image;
A configuration step of configuring the page image generated in the generation step as a job;
An image forming step of forming an image of the job configured in the configuration step;
A storage step of storing in the storage device together with time information an event that occurred during the image formation of the job in the image formation step;
When time information is input via the UI screen displayed on the operation unit, a specifying step of specifying a job and an event from the storage device based on the input time information;
A reproduction step of executing the job and event stored in the storage device sequentially from the job and event specified in the specifying step;
A program for running In a computer having an operation unit and a storage device,
A receiving step for receiving the job;
A generation step of developing the job received in the reception step and generating a page image;
An average value storing step for storing an average value of signal values of pixels of the page image generated in the generating step in the storage device together with time information;
A configuration step of configuring the page image generated in the generation step as a job;
An image forming step of forming an image of the job configured in the configuration step;
A storage step of storing in the storage device together with time information an event that occurred during the image formation of the job in the image formation step;
When time information is input via the UI screen displayed on the operation unit, an identification value that specifies an average value and an event of a pixel value of a pixel of a page image from the storage device based on the input time information Steps,
A page image generation step of generating a page image that is completely filled from an average value of signal values of pixels of the page image specified in the specifying step;
A reproduction step of performing reproduction sequentially by forming an image of the page image generated in the page image generation step and executing the event specified in the specification step;
A program for running In a computer having an operation unit and a storage device,
A receiving step for receiving the job;
A generation step of developing the job received in the reception step and generating a page image;
A mosaic image generation step of generating a mosaic image from the page image generated in the generation step;
A mosaic image storing step of storing the mosaic image generated in the mosaic image generating step together with time information in the storage device;
A configuration step of configuring the page image generated in the generation step as a job;
An image forming step of forming an image of the job configured in the configuration step;
A storage step of storing in the storage device together with time information an event that occurred during the image formation of the job in the image formation step;
When time information is input via the UI screen displayed on the operation unit, a specifying step of specifying a mosaic image and an event from the storage device based on the input time information;
A reproduction step of performing reproduction in sequence by forming an image of the mosaic image identified in the identification step and executing the event identified in the identification step;
A program for running

Images