JP2010049388A - Image processor and obstacle analyzing program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the analyzing precision of failure or the like based on history information. <P>SOLUTION: When the abnormal state of a sub-control part 64 is detected by a monitoring part 68A, or any analytic instruction is not made from a user, a picture image displayed by a GUI 26 is captured in response to the instruction of a capture instruction part 76, and recorded as log data together with a time when the picture image has been acquired in a log storage part 72. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image processing apparatus and a failure analysis program.

  Modern image processing devices are equipped with an advanced graphical user interface (GUI). The user can perform various processing settings by performing a predetermined operation while viewing the GUI. As a result, the user can use many functions with simple operations.

  If various functions are installed in this GUI, the software becomes large-scale, and it is not easy to confirm and reproduce the phenomenon when a failure occurs. For failure analysis, it is desirable to collect information at the timing of failure occurrence. In particular, high reliability is required for a backbone printer, and it is important to collect accurate analysis information.

Therefore, many printers are equipped with a function for collecting job records, system states, and the like as analysis information (see Patent Document 1).
JP 2002-149380 A

  As described above, failure analysis is performed based on analysis information collected on the printer. However, in the case of failures related to GUI software screen display and operation, log data that is character information alone is not sufficient as analysis information. There are many things. This is because the information displayed on the screen is constantly changing and it is extremely difficult to express graphical information with only characters. In particular, failure cases with poor reproducibility are likely to be difficult to investigate.

  An object of the present invention is to obtain an image processing apparatus and a failure analysis program capable of improving the analysis accuracy of a failure or the like based on history information, as compared with a case without this configuration.

  According to the first aspect of the present invention, a user interface module having a monitor screen for transmitting and receiving information relating to image processing and visually informing it, and monitoring means for monitoring the occurrence of a specific event occurring during image processing, And image data capturing means for capturing image data displayed on the monitor screen when the occurrence of the specific event is recognized by monitoring of the monitoring means.

  The invention according to claim 2 further comprises history information storage means for appropriately storing history information relating to the image processing in accordance with execution of the image processing in the invention according to claim 1, wherein the image data The image data captured by the capture means is stored in association with the history information stored in the history information storage means.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the image data capturing unit fails to capture image data due to failure of capturing conditions including at least a time limit. If you do, the import process will be canceled.

  According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects of the present invention, the specific event is caused by a load exceeding a steady operation capacity load continuing or accumulated for a certain period in the image processing control system. Is the time.

  According to a fifth aspect of the present invention, in the invention according to any one of the first to third aspects of the present invention, the non-operating capacity load is imposed on the image processing control system while the specific event is in a standby state other than the execution of the image processing. This is when the above load continues or accumulates.

  The invention according to claim 6 is the invention according to any one of claims 1 to 5, wherein the specific event is occurrence of a malfunction of the user interface module.

  According to a seventh aspect of the present invention, in the invention of the sixth aspect, an event that is a malfunction of the user interface module but does not require interrupting or canceling the image processing is excluded in advance from the specific event.

  The invention according to claim 8 is the invention according to any one of claims 1 to 7, wherein the specific event is an unresponsive operation related to image processing using the user interface module. is there.

  The invention according to claim 9 is the invention according to any one of claims 1 to 8, wherein the specific event is that the amount of image data accumulated in image processing exceeds a predetermined allowable amount. When

  The invention according to claim 10 is the invention according to any one of claims 1 to 9, wherein the specific event is that the amount of image data accumulated in image processing exceeds a predetermined rate of change. When

  The invention according to claim 11 is the invention according to any one of claims 1 to 10, wherein when the data amount of the image data stored by the history information storage means exceeds a certain amount, Delete image data from the oldest storage time.

  The invention according to claim 12 is a failure analysis program for causing a computer to function as the image processing apparatus according to any one of claims 1 to 11.

According to the invention described in claim 1 or claim 2, it is possible to improve the analysis accuracy of a failure or the like based on history information as compared with the case where the present configuration is not provided. Compared to the case where this configuration is not provided, useless processing can be omitted.

  According to the invention described in claims 4 to 10, the image data displayed on the monitor screen can be taken in at an appropriate timing as compared with the case where the present configuration is not provided.

  According to the eleventh aspect of the present invention, it is possible to effectively use the storage capacity as compared with the case where this configuration is not provided.

(Schematic configuration of the image processing apparatus 10)
FIG. 1 shows an image processing apparatus 10 according to the present embodiment. The image processing apparatus 10 is roughly classified into an image forming unit 12, a sheet storage unit 14, and a post-processing unit 16 from the left side in FIG.

  The image forming unit 12 is provided with a main control unit 20 that controls the entire image processing apparatus 10 on the upper surface of the casing 18. The main control unit 20 includes a control unit main body 22, a keyboard 24, a mouse 25, and a monitor 27. The input system of the keyboard 24 and mouse 25 and the output system of the monitor 27 are collectively referred to as “GUI 26”.

  A rectangular opening is provided on the right side of FIG. 1 of the main control unit 20 (the upper surface of the image forming unit 12). An opening / closing lid 32 is attached to the opening.

  An optical scanning unit that is covered by a casing 18 of the image forming unit 12 and that scans a light beam that emits light in accordance with image data from the main control unit 20, and a light beam that is scanned by the light scanning unit. A photosensitive drum on which a so-called electrostatic latent image is formed, a developing unit that develops the developer by supplying a developer such as toner to the electrostatic latent image on the photosensitive drum, and an image visualized by this development The image forming apparatus includes a transfer unit that transfers to a recording sheet and a fixing unit that fixes an image on the transferred recording sheet. Hereinafter, the above series of steps is referred to as “general image forming processing”.

  The front surface in FIG. 1 of the housing 18 in which the image forming unit 12 is accommodated is opened over substantially the entire area, and a pair of so-called double door opening / closing doors 34 is attached.

  Therefore, when the image forming unit 12 is maintained, the pair of opening / closing doors 34 is opened, so that a maintenance work space having substantially the same area as the entire surface of the housing 18 is provided.

  The recording sheet sent to the transfer unit of the image forming unit 12 is selectively taken out from the tray 36 provided at the lower part of the opening / closing lid 32 or a plurality of trays 38 provided in the sheet storage unit 14. ing. That is, the trays 36 and 38 can store recording papers of different sizes (they may be the same size), and any of the instructions from the image forming unit 12 based on an instruction from the main control unit 20 These trays 36 and 38 are selected, and for example, they are taken out in order from the uppermost recording sheet.

  The upper part of the paper storage unit 14 is a conveyance unit 40 for recording paper on which an image is formed. That is, the recording paper on which the image is formed by the image forming unit 12 is transported to the post-processing unit 16 via the transport unit 40 when post-processing is necessary. Note that recording paper that does not require post-processing is discharged to a discharge tray unit 42 disposed below the opening / closing lid 32.

  The post-processing unit 16 is also referred to as a finisher unit, for example, and performs bookbinding, binding, punching, folding, and other processing, and sorting processing in units of jobs and units.

(Control system of image processing apparatus 10)
As shown in FIG. 2, the image processing apparatus 10 according to the present embodiment is controlled by the main control unit 20. The main control unit 20 includes a control unit main body 22 and a GUI 26 as an input / output device.

  The control unit main body 22 comprehensively manages all processes. The control unit body 22 includes a CPU 44, a RAM 46, a ROM 48, an image data storage memory 62, an I / O (input / output unit) 50, and a bus 52 such as a data bus and a control bus for connecting them. A GUI 26 is connected to the I / O 50.

  The GUI 26 is configured to display an operation screen for selecting a menu, various setting screens, and a screen for informing the processing status of the image processing being executed. The user gives various instructions while looking at the display contents of the GUI 26.

  The image data storage memory 62 is composed of a hard disk or the like. The image data storage memory 62 is not limited to a hard disk, and an external storage device or the like may be used.

  In addition, an image formation control unit 56, a conveyance control unit 58, and a post-processing control unit 60 are connected to the control unit main body 22 via a communication interface (I / F) 51. Hereinafter, the image formation control unit 56, the conveyance control unit 58, and the post-processing control unit 60 are collectively referred to as a “sub control unit 64”.

  An instruction or the like input by the user using the GUI 26 is output to the control unit main body 22. On the other hand, information output from the control unit main body 22 is input to the GUI 26 and displayed on the GUI 26.

  The control unit main body 22 appropriately outputs various instructions to the sub-control unit 64. The sub control unit 64 to which the instruction is input controls to execute various image processing based on the instruction. The sub control unit 64 outputs the processing status, processing result, image data, and the like to the control unit main body 22.

  Further, the control unit main body 22 outputs an instruction to the sub-control unit 64 that performs the next image processing based on the input from the sub-control unit 64.

  Further, in the control unit main body 22, the image data input from the sub control unit 64 is stored in the image data storage memory 62. In the image data storage memory 62, image data being subjected to image processing is stored. The image data is deleted upon completion of the image processing.

(Log data generation and image data acquisition control)
The image processing apparatus 10 executes image processing by combining a plurality of functions based on the above configuration. Here, the image processing apparatus 10 records history information (log) regarding events that occur in the image processing apparatus 10, such as events that occur until image processing is completed. Further, the image processing apparatus 10 according to the present embodiment records the image data of the screen displayed on the GUI 26 as log data.

  FIG. 3 is a functional block diagram of the image processing apparatus 10 according to the present embodiment. This functional block diagram does not limit the hardware configuration, but is classified according to function.

  The user uses the GUI 26 to input a desired image processing instruction such as general image forming processing. The GUI 26 is connected to the analysis unit 66. The analysis unit 66 analyzes the user instruction content input via the GUI 26. Based on a user instruction, an execution instruction is output to each unit that executes the instruction.

  For example, the analysis unit 66 analyzes an image processing instruction input by the user. Note that, as an example of a user instruction, the image processing instruction is merely cited, and other various instructions are included, and the present invention is not limited thereto.

  The analysis unit 66 is connected to the image processing control unit 68. When the input instruction is an image processing instruction, the analysis unit 66 outputs the image processing instruction to the image processing control unit 68, reads out the image data from the image data storage memory 62, and outputs the image data to the image formation control unit 56. The image processing control unit 68 is connected to each of the image formation control unit 56, the conveyance control unit 58, and the post-processing control unit 60. The image processing control unit 68 selectively outputs an image processing command to the image formation control unit 56, the conveyance control unit 58, and the post-processing control unit 60 based on the input image processing instruction.

  Here, the image processing control unit 68 includes a monitoring unit 68A. The sub control unit 64 outputs information such as each processing status and processing result to the sequential monitoring unit 68A. Specifically, there is control information such as the start or end of each process execution, error information when an error occurs, and the like.

  The monitoring unit 68A is connected to the log generation unit 70. The monitoring unit 68A outputs the processing information input from the sub control unit 64 to the log generation unit 70.

  When the processing information is input from the monitoring unit 68A, the log generation unit 70 generates log data. The log data is, for example, the control information, error information, time information of the time of occurrence, etc. as shown in FIG.

  The log generation unit 70 is connected to the log storage unit 72. The log generation unit 70 outputs the generated log data to the log storage unit 72. The log storage unit 72 stores log data. The information recorded as log data is not limited to this.

  Further, the user can check the log data stored in the log storage unit 72. When a log data display instruction is input from the GUI 26 via the analysis unit 66, the display instruction is sent from the analysis unit 66 to the log storage unit 72.

  The log storage unit 72 is connected to the GUI display control unit 74. The log storage unit 72 outputs log data to the GUI display control unit 74 based on the input display instruction. The GUI display control unit 74 controls the GUI 26 to display log data. In many cases, the log data stored in the log storage unit 72 is copied to an external medium such as MO or CD-RW, and brought to a support center in charge of maintenance of the image forming apparatus. Investigate the cause and investigate countermeasures.

  By the way, since the log data includes error information, the log data is used as one piece of error analysis information after the error occurs. For error analysis, it is effective to collect information at the timing of error occurrence. In particular, in the case of a GUI module error, the GUI display information at the time of the error is effective for analysis. This is because what is displayed on the screen when the error occurs and the memory of the user who has used the apparatus is not always correct. Even if you confirm the situation at the time of the error for analysis at a later date, the necessary information cannot be obtained due to forgetting, or incorrect information may be transmitted due to incorrect memory of the user, and as a result, it may take time to analyze rather . For example, even when a certain error message is displayed on the screen, information that a message different from the actual message is displayed as a result of the user or the person in charge at the site may be transmitted. Furthermore, it is generally difficult to express the exact state of the screen with words alone in the failure of the GUI module. Therefore, in this embodiment, as shown in FIGS. 4B and 4C, a screen image of the display screen of the GUI 26 is recorded as log data. Since the screen image at the time of error occurrence is recorded as log data, the log data becomes valid information as error analysis information.

  Further, in order to avoid losing the timing of error occurrence, the monitoring unit 68A monitors the state of the sub-control unit 64 in this embodiment. Even a part of the abnormality in the sub-control unit 64 may cause an error. Therefore, the display screen is captured and recorded as log data when an abnormal state is detected. Note that screen capture refers to capturing image data displayed on the GUI 26.

  As shown in FIG. 3, the monitoring unit 68A accepts input of control information, error information, and the like from the sub-control unit 64, but no “abnormality” that causes a fault in the sub-control unit 64 has occurred. To monitor.

  Specifically, when any of the sub-control units 64 has been heavily loaded for a long time, there is a possibility that some software failure has occurred. Therefore, the monitoring unit 68A acquires any load information of the sub-control unit 64.

  Note that, when image processing is being executed, the load is usually high, so there is little possibility that the high load itself suggests the occurrence of a failure. Therefore, the monitoring unit 68A determines whether the sub control unit 64 is executing image processing or is waiting based on the control information input from the sub control unit 64 simultaneously with the acquisition of the load information. May be. That is, while the sub control unit 64 is executing image processing, the monitoring unit 68A stops monitoring the load state of the sub control unit 64. As a result, the monitoring unit 68A determines that it is in an abnormal state when it is confirmed that the sub-control unit 64 is in a high load for a certain time and is on standby.

  In addition, the monitoring unit 68A monitors the malfunction of the GUI module including the GUI 26. The GUI module includes a GUI display control unit 74 that displays information on the GUI 26, a sensor system that transmits information to the GUI display control unit 74, and the like. The monitoring unit 68A determines that the failure of the GUI module is in an abnormal state.

  The abnormal state here refers to a case where an inconsistency caused by a malfunction of the system, such as detecting a logical contradiction of data within the GUI module, is detected. For example, there is a case where an event indicating completion of printing is received for job data before starting printing, even though it is correct that the job status changes in the order of printing waiting, printing, and printing completion.

  In addition, as another abnormal state, it may be considered that a button that should not be pressed at a certain timing is actually pressed. For example, it is assumed that the button for pausing the device is correctly in an invalid state when it is already paused. However, if it is detected that the button is pressed even though it is temporarily stopped, there is a possibility that the screen control of the button display is defective. When log data including a GUI screen image is recorded, it is possible to accurately know what kind of screen display has been performed later, which is particularly effective in analyzing the occurrence of a defect in the GUI module.

  However, if a minor problem that has no possibility of causing an error to the system is already known, it is not necessary to record it as log data, so the monitoring unit 68A detects such an error. A minor defect may not be determined as an abnormal state. In the above example, if it is known in advance that there is no actual harm even if the pause button is pressed during the pause, it can be ignored even if the malfunction is detected.

  Further, the monitoring unit 68A monitors the amount of image data in the image data storage memory 62. The image data storage memory 62 stores only the image data being subjected to image processing, and is deleted when the image processing is completed. In other words, since the image data in the image data storage memory 62 is normally deleted upon completion of processing, the amount of stored image data falls within a certain amount. Further, since the sub-control unit 64 sequentially executes image processing, there is no sudden increase or decrease in the amount of stored image data.

  However, there may be operational problems such as data not being deleted after image processing is completed, or one of the sub-control units 64 not functioning properly and image processing is delayed. Therefore, the monitoring unit 68A monitors the amount of image data in the image data storage memory 62, and when it is confirmed that the predetermined allowable amount has been exceeded or the predetermined predetermined change rate has been exceeded, an abnormal state is detected. It is judged that.

  In addition, although the above was mentioned as an abnormal state of the sub-control part 64, it is not limited to this, The item which may become an error later can be made to monitor 68A. .

  When the monitoring unit 68 </ b> A detects an abnormal state of the sub-control unit 64, the monitoring unit 68 </ b> A outputs warning information to the log generation unit 70. The log generation unit 70 records log data together with time information at that time based on the warning information.

(Screen capture based on determination by monitoring unit 68A)
As shown in FIG. 3, the monitoring unit 68 </ b> A is connected to the capture instruction unit 76. The monitoring unit 68A detects an abnormal state of the sub-control unit 64 (here, a high CPU load is detected (see FIG. 4B)). The monitoring unit 68 </ b> A outputs a capture instruction to the capture instruction unit 76 along with the output of warning information to the log generation unit 70.

  The capture instruction unit 76 is connected to the GUI display control unit 74 and the capture execution unit 78. The capture instruction unit 76 outputs a capture instruction to the GUI display control unit 74 and the capture execution unit 78 based on the input from the monitoring unit 68A.

  The GUI display control unit 74 is connected to the GUI 26 and the capture execution unit 78. The GUI display control unit 74 acquires the screen image currently displayed on the GUI 26 based on the capture instruction from the capture instruction unit 76. The GUI display control unit 74 outputs the acquired screen image to the capture execution unit 78.

  The capture execution unit 78 is connected to the log generation unit 70. The capture execution unit 78 outputs the acquired screen image to the log generation unit 70 based on the capture instruction from the capture instruction unit 76. In the log generation unit 70, the acquired screen image and the time when the screen image is acquired are associated with each other and generated as log data.

  The log generation unit 70 outputs log data with a screen image to the log storage unit 72. In the log storage unit 72, log data with the screen image is stored together with normal log data (see FIG. 4B).

  Note that the screen image data capacity that can be stored in the log storage unit 72 is determined in advance, and when the specified capacity is exceeded, the screen image data may be deleted from the oldest storage time. Good. By setting, the screen image data that can be stored in the log storage unit 72 is kept constant without enlarging the capacity of the log data.

(For screen capture based on user instructions)
Analysis information including screen capture based on the user's instruction, such as when the user notices that some malfunction has occurred on the image processing apparatus 10 as well as when the monitoring unit 68A monitors the sub-control unit 64, etc. Is supposed to collect.

  The user inputs an analysis information collection instruction using the GUI 26. The instruction is input to the analysis unit 66, and the instruction content is analyzed. The analysis unit 66 is connected to the capture instruction unit 76. The analysis unit 66 outputs a capture instruction command to the capture instruction unit 76 based on the instruction content.

  When a capture instruction is input to the capture instruction unit 76, a screen image is acquired and stored in the log storage unit 72 as log data, as in the case of screen capture by the monitoring unit 68A (see FIG. 4C). ).

  At this time, the log data also records that an analysis information collection instruction has been given by the user (see FIG. 4C).

(Cancel screen capture)
When a capture instruction is given to the capture instruction unit 76 by an instruction from the monitoring unit 68A or a user, screen capture may be impossible for some reason. For example, the OS software, device driver, and hardware that control the screen are stopped for some reason. For these reasons, screen capture itself is often impossible.

  As illustrated in FIG. 3, the capture execution unit 78 acquires a screen image from the GUI display control unit 74 based on the capture instruction of the capture instruction unit 76.

  In this case, when the capture execution unit 78 fails to acquire the screen image, the monitoring unit 68A outputs a screen capture stop instruction to the capture instruction unit 76. The capture instruction unit 76 outputs a stop instruction to the capture execution unit 78, and the screen capture is stopped.

  As a condition for determining whether to stop the screen capture by the monitoring unit 68A, for example, the number of times that the capture instruction unit 76 outputs a capture instruction to the GUI display control unit 74 is counted. For example, a predetermined time has elapsed since the capture instruction was output.

  Note that screen capture cancellation is also recorded as log data.

  Hereinafter, the operation of the present embodiment will be described with reference to a flowchart showing execution of screen capture in FIG.

  In step 100, capture condition monitoring control is performed, and the process proceeds to step 102. The capture condition monitoring control in step 100 will be described later with reference to FIG.

  In step 102, it is determined whether or not the flag F = 1. This flag F is determined by the processing of FIG. If the determination in step 102 is affirmative (F = 1), the process proceeds to step 104 because the capture condition is satisfied. On the other hand, if a negative determination is made in step 102 (F = 0), the capture condition is not satisfied and it is not the time of screen capture, so this routine ends.

  In the next step 104, screen capture is instructed by the capture instruction unit 76, and the process proceeds to step 106.

  In step 106, it is determined whether the capture execution unit 78 has acquired a screen image. If an affirmative determination is made in step 106 (screen image acquisition), the process proceeds to step 108, and if a negative determination is made (screen image not acquired), the process proceeds to step 110.

  In the next step 108, since the acquisition of the screen image is completed, the acquired screen image is stored in the log storage unit 72 as log data together with the acquisition time in the log generation unit 70.

  On the other hand, in step 110, since the screen image is not acquired, it is determined whether or not a predetermined time has elapsed since the capture instruction unit 76 first output the instruction. When an affirmative determination is made at step 110 (elapse of a predetermined time), the routine proceeds to step 112. On the other hand, if a negative determination is made in step 110 (a predetermined time has not elapsed), the process returns to step 106.

  In step 112, since screen capture is impossible, the monitoring unit 68A issues a screen capture stop instruction.

  FIG. 6 is a flowchart showing the capture condition monitoring control (step 100) described in the flowchart of FIG.

  In step 200, the flag F = 0 is set as an initial state.

  In step 202, it is determined whether a capture instruction is input from the user. If the determination in step 202 is affirmative (capture instruction by the user), the process proceeds to step 214.

  On the other hand, if a negative determination is made at step 202 (no instruction from the user), the routine proceeds to step 204. Thereafter, the process proceeds to the determination of whether or not the screen capture is abnormal.

  In the next step 204, the monitoring unit 68A determines whether any of the sub-control units 64 has a high load. If an affirmative determination is made in step 204 (high load), the process proceeds to step 206 on the assumption that any of the sub-control units 64 may be in an abnormal state.

  On the other hand, if a negative determination is made in step 204 (not a high load), the process proceeds to step 208 because the sub control unit 64 is not in an abnormal state.

  In the next step 206, it is determined whether or not the high-load sub-control unit 64 is on standby. If an affirmative determination is made in step 206 (standby), it can be determined that the sub-control unit 64 is in an abnormal state, and the process proceeds to step 214.

  On the other hand, if a negative determination is made in step 206 (during image processing), the sub-control unit 64 is not in an abnormal state because it is a normal high-load state due to image processing execution. Therefore, the process proceeds to step 208.

  In step 208, it is determined whether or not a failure has occurred in the GUI module. If the determination in step 208 is affirmative (problem has occurred), the process proceeds to step 214. Note that minor problems are excluded as GUI module problems.

  On the other hand, if a negative determination is made in step 208 (no failure occurs or a minor failure occurs), the process proceeds to step 210.

  In step 210, it is determined whether or not the data amount of the image data storage memory 62 exceeds the allowable amount. If an affirmative determination is made in step 210 (exceeding the allowable amount), the process proceeds to step 214 because image processing has not been performed normally. On the other hand, if a negative determination is made at step 210 (below the allowable amount), the routine proceeds to step 212.

  In step 212, it is determined whether or not the rate of change of the data amount in the image data storage memory 62 has exceeded a predetermined rate of change. If an affirmative determination is made in step 212 (exceeding a predetermined change rate), as in the affirmative determination in step 210, the image processing is abnormal, and the process proceeds to step 214.

  On the other hand, if a negative determination is made in step 212 (within a predetermined rate of change), the capture condition has not been established, and this routine ends because it is not the case that the screen should be captured.

  In step 214, the capture condition is established. Therefore, F = 1 is set, and this routine ends.

  In the present embodiment, the acquired screen image and the acquisition time are stored in the log storage unit 72 as one log data. However, the log data consisting of the screen image and the acquisition time is separate from the normal log data. You may make it store.

1 is an overall schematic diagram showing an image processing apparatus according to the present embodiment. It is a figure which shows the hardware constitutions of the image processing apparatus which concerns on this embodiment. It is a functional block diagram of the image processing apparatus which concerns on this Embodiment. It is a figure which shows an example of the log data concerning this Embodiment. It is a flowchart which shows execution of the screen capture which concerns on this Embodiment. 10 is a flowchart for determining whether a capture condition is satisfied according to the present embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Image processing apparatus 12 Image forming part 14 Paper storage part 16 Post-processing part 18 Case 20 Main control part 22 Control part main body 24 Keyboard (user interface module)
25 Mouse (User interface module)
26 GUI (User Interface Module)
27 Monitor (User interface module)
32 Opening / Closing Lid 34 Opening / Closing Door 36 Tray 38 Multiple Tray 40 Transport Unit 42 Discharge Tray Unit 44 CPU
46 RAM
48 ROM
50 I / O
51 I / F
52 Bus 56 Image Formation Control Unit 58 Transport Control Unit 60 Post-Processing Control Unit 62 Image Data Storage Memory 64 Sub Control Unit 66 Analysis Unit (Monitoring Unit)
68 Image processing control unit 68A Monitoring unit (monitoring means)
70 Log generator (history information storage means)
72 Log storage unit (history information storage means)
74 GUI display control unit (user interface module, image data fetching means)
76 Capture instruction section (Image data capture means)
78 Capture execution unit (Image data capture means)

Claims (12)

A user interface module with a monitor screen for visually transmitting and receiving information on image processing;
Monitoring means for monitoring the occurrence of a specific event that occurs during image processing;
Image data capturing means for capturing image data displayed on the monitor screen when the occurrence of the specific event is recognized by monitoring of the monitoring means;
An image processing apparatus. In accordance with the execution of image processing, it further includes history information storage means for appropriately storing history information related to the image processing,
The image processing apparatus according to claim 1, wherein the image data captured by the image data capturing unit is stored in association with the history information stored in the history information storage unit.   The image processing apparatus according to claim 1, wherein the image data capturing unit stops the capturing process when the capturing of the image data fails due to failure of capturing conditions including at least a time restriction.   The image processing apparatus according to any one of claims 1 to 3, wherein the specific event is when a load equal to or higher than a steady operation capacity load continues or accumulates for a certain period in the image processing control system.   The image processing apparatus according to any one of claims 1 to 3, wherein the specific event is when a load exceeding the non-operating capacity load continues or accumulates in the image processing control system during standby other than execution of image processing.   The image processing apparatus according to claim 1, wherein the specific event is a failure of the user interface module.   The image processing apparatus according to claim 6, wherein an event that is a malfunction of the user interface module but does not require interrupting or canceling the image processing is excluded in advance from the specific event.   The image processing apparatus according to claim 1, wherein the specific event is when an operation related to image processing using the user interface module is unresponsive.   The image processing apparatus according to claim 1, wherein the specific event is when the amount of image data accumulated in image processing exceeds a predetermined allowable amount.   The image processing apparatus according to claim 1, wherein the specific event is when the amount of image data accumulated in image processing exceeds a predetermined change rate.   The image processing device according to any one of claims 1 to 10, wherein when the amount of image data stored by the history information storage means exceeds a certain amount, the image data is deleted in order of oldest storage time. .   A failure analysis program for causing a computer to function as the image processing apparatus according to any one of claims 1 to 11.

Images