JP2019205050A - Image processing system - Google Patents

Abstract

To provide an image processing system that can appropriately reflect both of processing on a server side and processing on an image processing device side.SOLUTION: A server unit 20 requests an MFP unit 10 to execute a job according to instructions on job execution from a user. The MFP unit 10 generates image data by scanning a document as the job, transmits the image data to a server unit 20, and counts down an account value of the user in an MFP-side count value DB 15 on the basis of the scanning. The server unit 20 transmits the image data received from the MFP unit 10, counts down a count value of the user in a server-side count value DB 27, and then transmits the count value in the server-side count value DB 27 to the MFP unit 10. The MFP unit 10 updates the count value in the MFP-side count value DB 15 by the count value transmitted from the server unit 20.SELECTED DRAWING: Figure 3

Description

  The present disclosure relates to an image processing system, and more particularly, to an image processing system in which a server and an image processing apparatus cooperate to process image data.

  A conventional image processing apparatus such as an MFP (Multi-Functional Peripheral) manages count information according to the contents of image processing for billing and the like, and further, such count information is managed by a server. was there. Such image processing apparatuses include, for example, Japanese Unexamined Patent Application Publication No. 2009-169687 (Patent Document 1), Japanese Unexamined Patent Application Publication No. 2010-074377 (Patent Document 2), and Japanese Unexamined Patent Application Publication No. 2006-164720 (Patent Document 3). Is disclosed.

JP 2009-169687 A JP 2010-074377 A Japanese Patent Laid-Open No. 2006-164720

  In recent years, image data generated in an image processing apparatus may be processed on the server side. In such a case, it is necessary to link the count information on the image processing apparatus side with the count information on the server side. However, conventionally, the image processing apparatus and the server operate independently of each other, each holds count information, and updates each count information according to processing in each apparatus. Therefore, when the image processing apparatus and the server process data as one system, unified management of count information in the image processing apparatus and the server is desired.

  In an example of a specific embodiment, an administrator of the system can check the count information of the image processing apparatus by a count information display function using an administrator menu. The administrator can also check the server count information. When each of the image processing apparatus and the server updates the count information, the count information of the image processing apparatus and the count information of the server usually do not match. For this reason, the administrator does not know which count information should be used to identify the system usage status, and is likely to be confused.

  The present disclosure has been conceived in view of such circumstances, and an object thereof is to provide a technique for appropriately managing count information in an image processing system in which a server and an image processing apparatus cooperate. .

  According to an aspect of the present disclosure, an image processing system including an image processing device and an information processing device capable of communicating with the image processing device is provided. The information processing device includes a first storage unit that stores count information related to the first user, a request unit that requests the image processing device to generate image data in association with the first user, Processing means for processing the image data generated in response to the request, and first update means for updating the count information in the first storage means in accordance with the processing by the processing means. The image processing apparatus includes a second storage unit that stores count information related to the first user, a generation unit that generates image data in response to a request, and a second storage unit according to generation of image data by the generation unit. Second update means for updating count information associated with the first user stored in the means. The information processing apparatus further includes synchronization means for communicating with the image processing apparatus in order to synchronize the count information in the first storage means and the count information in the second storage means.

  According to another aspect of the present disclosure, an image processing system is provided that includes an image processing device, an information processing device that can communicate with the image processing device, and a server that can communicate with the information processing device. The server includes first storage means for storing count information associated with the first user. The information processing apparatus includes a request unit that requests the image processing apparatus to generate image data in association with the first user, a processing unit that processes image data generated in response to the request, and a processing unit. First update means for updating the count information in the first storage means in accordance with the processing. The image processing apparatus includes a second storage unit that stores count information related to the first user, a generation unit that generates image data in response to a request, and a second storage unit according to generation of image data by the generation unit. Second update means for updating count information associated with the first user stored in the means. The information processing apparatus further includes synchronization means for communicating with the image processing apparatus in order to synchronize the count information in the first storage means and the count information in the second storage means.

  The processing by the processing means may include at least one type of processing among image size change, image color change, and image pixel number change. The first update unit may update the count information in the first storage unit in a manner according to the type of processing executed by the processing unit.

  When the image processing apparatus is executing an image processing operation, the synchronization unit may execute communication for synchronization after the execution of the image processing operation.

  The synchronization means may request the image processing apparatus to set a synchronization request flag, which is a flag for synchronization, when the image processing apparatus is executing an image processing operation. The image processing apparatus may further include setting means for setting the synchronization request flag in the image processing apparatus in response to a request for setting the synchronization request flag. When the synchronization request flag is set, the second update means requests the synchronization means for communication for synchronizing the count information in the first storage means and the count information in the second storage means. May be.

  The synchronization unit requests the image processing apparatus to stop the image processing operation related to the first user when the count information in the first storage unit reaches the upper limit assigned to the first user. May be.

  The synchronization unit requests the image processing apparatus to resume the image processing operation related to the first user when the upper limit of the count information assigned to the first user is updated in the first storage unit. Also good.

  The synchronization means synchronizes the count information in the first storage means and the count information in the second storage means when the image data generated in response to the request is deleted without being processed by the processing means. In order to do so, communication with the image processing apparatus may be performed.

  According to the present disclosure, when the count information in the information processing apparatus is updated, the synchronization unit of the information processing apparatus synchronizes the count information in the information processing apparatus and the count information in the image processing apparatus.

1 is a diagram illustrating an appearance of an information processing device 100 that is an example of an image processing system. 2 is a diagram illustrating a hardware configuration of an information processing device 100. FIG. 4 is a diagram for explaining synchronization of count information in the MFP unit 10 and count information in the server unit 20 in the information processing apparatus 100. FIG. 4 is a diagram for explaining synchronization of count information in the MFP unit 10 and count information in the server unit 20 in the information processing apparatus 100. FIG. It is a figure which shows an example of the synchronization of a count value. It is a figure which shows the other example of the synchronization of a count value. 4 is a flowchart of an example of processing executed by a CPU 250 of the server unit 20 when a user logs in to the information processing device 100. It is a flowchart of the subroutine of step S26 of FIG. 3 is a flowchart illustrating an example of processing executed by a CPU 150 of the MFP unit 10 when a user logs in to the information processing apparatus 100. 7 is a flowchart of processing executed by the MFP unit 10 in response to a re-login request from the server unit 20 in step S34 (FIG. 7). It is a flowchart of the modification of the process of FIG. It is a figure which shows the modification of a structure of an image processing system. It is a figure which shows an example of a functional structure of the image processing system of FIG.

  An embodiment of an image processing system will be described below with reference to the drawings. In the following description, the same parts and components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, these descriptions will not be repeated.

[1. Configuration of image processing system]
FIG. 1 is a diagram illustrating an appearance of an information processing apparatus 100 that is an example of an image processing system. FIG. 2 is a diagram illustrating a hardware configuration of the information processing device 100. The information processing device 100 is realized as a device that integrally configures a server and an MFP. The configuration of the information processing device 100 will be described with reference to FIGS. 1 and 2.

  The information processing device 100 includes an MFP unit 10, a server unit 20, and an operation panel 30. The operation panel 30 is used as a user interface for the MFP unit 10 and the server unit 20. Hereinafter, configurations of the MFP unit 10 and the server unit 20 will be described.

(MFP unit 10)
The MFP unit 10 includes a CPU (Central Processing Unit) 150 for controlling the entire MFP unit 10 and a storage unit 160. The storage unit 160 is realized by, for example, a nonvolatile memory. The information stored in the storage unit 160 may include a program executed by the CPU 150 and data used for executing the program. An example of data is count information for each user. The count information includes, for example, a value obtained by counting the usage status of the function of the information processing device 100.

  The MFP unit 10 further includes an image processing unit 151, an image forming unit 152, an image reading unit 153, and an internal interface 180. The image processing unit 151 performs processing such as enlargement / reduction of an output image, for example, by processing the input image data. The image processing unit 151 is realized by, for example, an image processing processor and a memory. The image forming unit 152 includes hardware resources for forming an image on the recording paper, such as a toner cartridge, a paper tray for storing the recording paper, and a photoconductor, and hardware for conveying the recording paper. Realized by resources. The image reading unit 153 is realized by hardware resources configured to create image data of a document such as a scanner. As the functions of the image processing unit 151, the image forming unit 152, and the image reading unit 153, those well-known in the image forming apparatus can be adopted, and thus detailed description thereof will not be repeated here.

  The internal interface 180 functions as an interface for communication with the server unit 20, and is realized by, for example, a LAN (Local Area Network) card.

(Server unit 20)
The server unit 20 includes a CPU 250 for controlling the entire server unit 20, a network communication unit 260, a storage unit 270, and an internal interface 280.

  The network communication unit 260 is realized by hardware resources configured to execute data transmission / reception with an external device such as a user's PC (Personal Computer) via a global network. An example of the hardware resource is a network card. The CPU 250 communicates with an external device via the network communication unit 260.

  The storage unit 270 is realized by, for example, a nonvolatile memory. The information stored in the storage unit 270 may include a program executed by the CPU 250 and data used for executing the program. An example of data is count information for each user. The count information includes, for example, a value obtained by counting the usage status of the function of the information processing device 100.

  The CPU 250 is further configured to control the operation panel 30. The operation panel 30 includes a control circuit 350, a display unit 360 realized by an organic EL (Electro Luminescence) display or the like, and an operation unit 370 realized by a touch sensor or the like.

  The control circuit 350 controls the display operation of the display unit 360 according to a control signal from the CPU 250. The operation unit 370 outputs the input information to the control circuit 350. The control circuit 350 outputs a signal corresponding to information input from the operation unit 370 to the CPU 250.

[2. Management of count information in image processing system]
3 and 4 are diagrams for explaining the synchronization of the count information in the MFP unit 10 and the count information in the server unit 20 in the information processing apparatus 100. FIG. Both FIG. 3 and FIG. 4 show functional configurations of the MFP unit 10 and the server unit 20. FIG. 3 shows a data flow related to a job request from the server unit 20 to the MFP unit 10. FIG. 4 shows an outline of processing in which the count information in the MFP unit 10 is synchronized with the count information in the server unit 20. Hereinafter, after describing the functional configurations of the MFP unit 10 and the server unit 20, the contents of the processes shown in FIGS. 3 and 4 will be described.

(Functional configuration of MFP unit 10)
The MFP unit 10 includes a login processing unit 11, a scan counter processing unit 12, a scan execution unit 13, a scan data transfer processing unit 14, and an MFP side count value DB (database) 15.

  The login processing unit 11 executes processing for login from the server unit 20 to the MFP unit 10 and is realized by the CPU 150 that executes a given program, for example.

  The scan counter processing unit 12 manages count information for each user. An example of management is to count down the count value stored as the count information according to the usage status of the image processing function in the MFP unit 10. An example of the image processing function is image data generation (scanning function) by the image reading unit 153. For example, the count value is counted down by “1” by generating image data by scanning one page of the document.

  In one example, the scan counter processing unit 12, when a count value of “100” is assigned to the user A, the image data of a one-page document while the user A is logged in the information processing apparatus 100. Is generated, the count value of the user A is counted down by “1”. As a result, the count value of the user A changes to “99”.

  The scan execution unit 13 executes an image processing function in the MFP unit 10. An example of the image processing function is image data generation (scanning function) by the image reading unit 153. An example of the scan execution unit 13 is an image reading unit 153.

  The scan data transfer processing unit 14 transmits the image data generated in the MFP unit 10 to the server unit 20 and is realized by, for example, the internal interface 180.

  The MFP-side count value DB 15 stores a count value for each user, and is realized by the storage unit 160, for example.

(Functional configuration of server unit 20)
The server unit 20 includes a login processing unit 21, a determination unit 22, a request processing unit 23, an upper limit counter processing unit 24, a preview processing unit 25, a data processing unit 26, a server-side count value DB 27, and data storage. 28.

  The login processing unit 21 is realized by a CPU 250 that requests login to the MFP unit 10 of the server unit 20 and executes a given program, for example.

  The determination unit 22 determines whether or not the count information on the MFP unit 10 side needs to be synchronized with the count information on the server unit 20 side by processing the image data in the server unit 20, and executes a given program, for example. This is realized by the CPU 250.

  The request processing unit 23 requests the MFP unit 10 to execute an image processing function based on a user instruction. The request processing unit 23 is realized by, for example, the CPU 250 that executes a given program.

  The upper limit counter processing unit 24 is realized by the CPU 250 that updates the count value associated with the authenticated user based on the processing performed on the image data in the server unit 20, and executes a given program, for example. The

  The preview processing unit 25 is realized by the CPU 250 that displays a preview screen of the image data acquired from the MFP unit 10 on the display unit 360 of the operation panel 30 and executes a given program, for example.

  The data processing unit 26 executes various processes on the image data acquired from the MFP unit 10. The processing that is performed may include changing the image size, changing the color of the image, and / or changing the number of pixels in the image. The processing performed may include transmission to an external server and / or transmission as an email attachment. The data processing unit 26 is realized, for example, by the CPU 250 that executes a given program, or by the CPU 250 and the network communication unit 260.

  The server-side count value DB 27 stores count information for each user, and is realized by the storage unit 270, for example.

  The data storage 28 stores image data, and is realized by the storage unit 270, for example.

(Job request from the server unit 20 to the MFP unit 10)
In FIG. 3, an alternate long and short dash line arrow represents a signal flow in a job request from the server unit 20 to the MFP unit 10.

  When the user inputs the user ID and password to the operation panel 30, the CPU 250 of the server unit 20 authenticates the user. When the user further inputs an instruction to execute an image processing function in the MFP unit 10 (for example, scanning a document) to the operation panel 30, the request processing unit 23 sends an image to the scan execution unit 13 of the MFP unit 10. Request execution of a processing function (eg, scan).

  In response to the request, the scan execution unit 13 scans the document and generates image data of the document. The scan data transfer processing unit 14 transmits the generated image data to the server unit 20.

  The preview processing unit 25 of the server unit 20 displays a preview image of the image data transmitted from the scan data transfer processing unit 14 on the display unit 360. In server unit 20, CPU 250 accepts a user instruction for image data generated in MFP unit 10.

  The instruction may be image processing for image data. The image processing is, for example, changing the image size, changing the color of the image, and / or changing the number of pixels of the image. When the image processing is instructed, the data processing unit 26 executes the instructed image processing.

  The instruction may be transmission of image data. When instructed to transmit image data, the data processing unit 26 transmits the image data to a destination included in the instruction. The image data to be transmitted may be one after image processing by the data processing unit 26, or one that is not subjected to image processing by the data processing unit 26 (one that has been transmitted from the scan data transfer processing unit 14). It may be.

  The instruction may be saving of image data. When instructed to save, the data processing unit 26 stores (saves) the image data in the data storage 28. The stored image data may be after image processing by the data processing unit 26, or may not be subjected to image processing by the data processing unit 26.

  The instruction may be deletion of image data. When the deletion is instructed, the data processing unit 26 deletes the image data. The image data to be deleted may be after image processing by the data processing unit 26, or may not be subjected to image processing by the data processing unit 26.

  The upper limit counter processing unit 24 updates the count value in the upper limit counter processing unit 24 in accordance with the content of the processing on the image data by the data processing unit 26. In one example, the count value is counted down by “0.5” for each type of data conversion for one page of image data. Types of data conversion include, for example, size change, change from color to monochrome, change from monochrome to color, and change in the number of pixels.

  In another example, the count value is counted down every time one page of image data is transmitted to one destination. More specifically, every time monochrome image data for one page is transmitted to one destination outside the information processing apparatus 100, the count value is counted down by “0.5”, and a color image for one page is obtained. When data is transmitted outside the information processing apparatus 100, the count value is counted down by “1.0”. For example, when monochrome image data for one page is transmitted to two destinations, the count value is counted down by “1.0”.

  The relationship between the processing content (data conversion, transmission) for the image data and the value counted down is stored in the storage unit 160 as an “attribute map”, for example.

  When the data processing unit 26 executes the processing of the image data, the determination unit 22 needs to synchronize the count information in the server unit 20 and the count information in the MFP unit 10 for the user who has logged into the information processing device 100. And the login processing unit 21 is requested to log in to the MFP unit 10.

(Synchronization of count information in MFP unit 10 and count information in server unit 20)
Referring to FIG. 4, the synchronization when it is determined that the count information in server unit 20 and the count information in MFP unit 10 need to be synchronized will be described. In FIG. 4, a broken arrow represents a signal flow related to synchronization of count values from the server unit 20 to the MFP unit 10.

  As described in FIG. 3, when the determination unit 22 requests login to the MFP unit 10, the login processing unit 11 causes the server unit 20 to log in to the MFP unit 10 and log in to the MFP unit 10. Thereafter, the determination unit 22 of the server unit 20 transmits the count value stored in the server-side count value DB 27 for the user who has logged into the information processing device 100 to the scan counter processing unit 12 of the MFP unit 10. The scan counter processing unit 12 updates the count value stored in the MFP-side count value DB 15 with the count value transmitted from the determination unit 22. As a result, the count value in the server unit 20 and the count value in the MFP unit 10 are synchronized.

[3. Specific example of count value synchronization]
(Specific example 1)
FIG. 5 is a diagram illustrating an example of count value synchronization. FIG. 5 shows four states (states A1 to A4) of the information processing device 100.

  The state A1 represents a state when the user logs into the information processing apparatus 100. The login processing unit 21 of the server unit 20 transmits the count value stored in the server-side count value DB 27 for the user to the MFP unit 10 in response to the login of the user. In the MFP unit 10, the transmitted count value is transmitted to the MFP side count value DB 15 via the login processing unit 11 and the scan counter processing unit 12. Accordingly, the count value of the user is synchronized between the server unit 20 and the MFP unit 10 when the user logs in. “100” is shown as an example of the count value of the user.

  A state A2 represents a state where the MFP unit 10 has updated the count value of the user. When requested by the request processing unit 23 of the server unit 20, the scan execution unit 13 of the MFP unit 10 generates image data by scanning a document. The scan data transfer processing unit 14 of the MFP unit 10 transmits the generated image data to the server unit 20.

  In response to the generation of the image data, the scan counter processing unit 12 of the MFP unit 10 counts down the user's count value by “1”. As a result, the count value of the user is changed to “99” in the MFP-side count value DB 15 of the MFP unit 10. On the other hand, in the server unit 20, since the image processing has not yet been executed, the count value of the user in the server-side count value DB 27 remains “100”.

  A state A3 represents a state in which the data processing unit 26 of the server unit 20 transmits the image data transmitted from the MFP unit 10 to five destinations by E-mail.

  In the example of FIG. 5, monochrome image data is used as the image data. Accordingly, the upper limit counter processing unit 24 of the server unit 20 counts down the count value in the server-side count value DB 27 of the user by “2.5” in response to the transmission of the image data. “2.5” is a value derived based on the transmission of monochrome image data per destination being “0.5” and being transmitted to five destinations. As a result of the countdown, the count value of the user in the server-side count value DB 27 is changed to “97.5”. On the other hand, the count value of the MFP-side count value DB 15 of the MFP unit 10 is “99”.

  A state A4 represents a state in which the count value in the server unit 20 and the count value in the MFP unit 10 are synchronized after processing in the server unit 20.

  When the data processing unit 26 processes the image data (data transmission), the determination unit 22 determines that a state that requires synchronization of the count value between the server unit 20 and the MFP unit 10 has occurred, and the MFP The unit 10 is requested to log in the server unit 20. When the server unit 20 logs in to the MFP unit 10, the determination unit 22 transmits the count value of the user in the server-side count value DB 27. The scan counter processing unit 12 of the MFP unit 10 updates the count value (“99”) in the MFP-side count value DB 15 with the transmitted count value (“97.5”) for the user. As a result, the same count value (“97.5”) as the count value stored in the server-side count value DB 27 is stored in the MFP-side count value DB 15 for the user. As a result, the count value in the server unit 20 and the count value in the MFP unit 10 are synchronized for the user.

(Specific example 2)
FIG. 6 is a diagram illustrating another example of count value synchronization. FIG. 6 shows four states (states B1 to B4) of the information processing apparatus 100.

  The state B1 is the state A3 in FIG. 5 (the determination unit 22 determines that a state that requires synchronization of the count value between the server unit 20 and the MFP unit 10 has occurred, and the login of the server unit 20 to the MFP unit 10 is performed. The MFP unit 10 is executing a job.

  In the state B1, for example, when the user who has instructed scanning and transmission of the document described with reference to FIG. 5 has further instructed scanning and transmission of another document, the MFP unit 10 causes the other document to be scanned. This corresponds to a state in which scanning is executed.

  In state A3, in response to the login request from the determination unit 22 of the server unit 20, the login processing unit 11 of the MFP unit 10 replies that the MFP unit 10 is executing a job. In response to the reply, the determination unit 22 suspends the login request for synchronizing the count values. As will be described later as state B4, determination unit 22 transmits the suspended login request again after the job is completed in MFP unit 10.

  A state B2 represents a state in which image data generated by scanning another document is transmitted from the MFP unit 10 to the server unit 20. By another document scanning operation, the count value of the MFP-side count value DB 15 of the MFP unit 10 is further reduced by “1” from the value indicated in the state A3. As a result, the count value in the MFP-side count value DB 15 is changed from “99” to “98”.

  A state B3 represents a state in which the server unit 20 transmits the image data transmitted from the MFP unit 10 in the state B2 as an E-mail attachment. In the example of FIG. 6, color image data is employed as data generated as image data of “another document”. In the information processing device 100, the count value is counted down by “1” for each page by transmitting color image data. As a result, the count value of the server-side count value DB 27 is counted down by “1” from the value indicated in the state A3. That is, the count value of the server-side count value DB 27 is changed from “97.5” to “96.5”.

  A state B4 represents a state in which the count value in the server unit 20 and the count value in the MFP unit 10 are synchronized after the processing in the server unit 20. As described in the state B3, when the data processing unit 26 of the server unit 20 processes the image data (data transmission), the determination unit 22 determines the count value between the server unit 20 and the MFP unit 10. It is determined that a state requiring synchronization has occurred, and the MFP unit 10 is requested to log in to the server unit 20. The login request also functions as a retransmission of the login request suspended in the state B1.

  When the server unit 20 logs in to the MFP unit 10, the determination unit 22 transmits the count value of the user in the server-side count value DB 27. The scan counter processing unit 12 of the MFP unit 10 updates the count value (“98”) in the MFP-side count value DB 15 with the transmitted count value (“96.5”) for the user. As a result, the same count value (“96.5”) as the count value stored in the server-side count value DB 27 is stored in the MFP-side count value DB 15 for the user.

  As described above with reference to FIG. 6, when the server unit 20 requests the MFP unit 10 to log in for synchronization of the count value, if the MFP unit 10 is executing a job, Then, after the job in the MFP unit 10 is completed, the login is requested again.

  Thereby, after the job of the MFP unit 10 is completed, the count value in the server unit 20 and the count value in the MFP unit 10 are synchronized for the user.

[4. Process flow on the server side]
FIG. 7 is a flowchart of an example of processing executed by the CPU 250 of the server unit 20 when the user logs in to the information processing device 100. The processing is realized by the CPU 250 executing a given program, for example. The contents of the process will be described with reference to FIG.

  In step S10, CPU 250 authenticates the user using the user ID and password input on operation panel 30.

  In step S12, CPU 250 requests MFP unit 10 to log in server unit 20 (state A1 in FIG. 5).

  In step S 14, CPU 250 transmits the count value of the authenticated user to MFP unit 10. The transmitted count value is stored in the server-side count value DB 27, that is, the count value on the server unit 20 side.

  In this example, the server unit 20 receives a scan job instruction from the user via the operation panel 30. In response, in step S16, CPU 250 requests MFP unit 10 to execute a scan job.

  In step S18, CPU 250 receives scan data (image data generated by a scan job) transmitted from MFP unit 10.

  In step S20, CPU 250 displays a preview of the received scan data on display unit 360.

  In step S22, CPU 250 determines whether the scan data has been deleted without being transmitted or stored. In the present embodiment, the fact that the scan data is deleted without being transmitted or stored is an example that the scan data is deleted without being processed in the server unit 20. In the information processing apparatus 100, the user can instruct image processing, transmission, and / or storage of scan data while viewing the preview image displayed in step S2, for example. Here, “save” means, for example, storing the scan data in the data storage 28.

  If CPU 250 determines that the scan data has been deleted without being transmitted or saved (YES in step S22), it sets a synchronization flag in step S24 and advances control to step S28. Note that the synchronization flag is reset in the initial state of the server unit 20. On the other hand, when CPU 250 determines that at least one of transmission and storage has been performed on the scan data, control proceeds to step S26.

  FIG. 8 is a flowchart of the subroutine of step S26 in FIG. The contents of step S26 will be described with reference to FIG.

  In step S260, CPU 250 determines whether or not a transmission instruction has been issued for the scan data. If CPU 250 determines that a transmission instruction has been issued (YES in step S260), control proceeds to step S264, and if not (NO in step S260), control proceeds to step S262.

  In step S262, CPU 250 counts down the count value in server-side count value DB 27 for the authenticated user in accordance with the contents of the process performed on the scan data. “Processing” in step S262 means data conversion for scan data.

  The relationship between the content of the image processing and the value to be counted down is defined in, for example, an attribute map. In one example, the attribute map specifies that the value “0.5” is counted down for each page of image data for each of resizing (eg, A4 → A3) and color to monochrome conversion. doing. In this case, when the user changes the size of scan data for one page from A4 to A3, changes from color data to monochrome data, and saves the changed scan data in the data storage 28, the count of the user is increased. The value is counted down by “1.0”.

  In step S264, CPU 250 counts down the count value in server-side count value DB 27 for the authenticated user in accordance with the content of the process performed on the scan data. “Processing” in step S264 means transmission of scan data. When data conversion is performed on scan data before transmission, in step S264, a value corresponding to the data conversion is added to the value to be counted down.

  The value counted down according to the conversion and transmission of data is defined in the above attribute map, for example. Regarding data transmission, the value for transmission of monochrome image data of one page is “0.5” for one destination. For one destination, the value for transmission of color image data of one page is “1.0”. For example, if the user changes the size of color image data for one page from A4 to A3 and then sends it to three destinations, the count value of the user is “3.5” (0.5 + 1.0 × 3) Count down.

  In step S266, CPU 250 sets a synchronization flag and returns control to FIG.

  Returning to FIG. 7, after executing the scan data processing in step S26 or after the control in step S24, in step S28, the CPU 250 determines whether or not the synchronization flag is set. If CPU 250 determines that the synchronization flag is set (YES in step S28), it resets the synchronization flag and proceeds to step S30, otherwise (NO in step S28), the process of FIG. End.

  In step S30, CPU 250 determines whether MFP unit 10 is executing a job. CPU 250 advances control to step S32 if MFP section 10 is executing a job (YES in step S30), and advances control to step S34 if not (NO in step S30).

  In step S 32, CPU 250 waits for a job completion notification from MFP unit 10. Upon receiving a job completion notification from the MFP unit 10, the CPU 250 advances the control to step S34.

  In step S <b> 34, CPU 250 requests MFP unit 10 to re-login server unit 20.

  In step S36, CPU 250 transmits the count value stored in server-side count value DB 27 for the user authenticated in step S10, to MFP unit 10 to which server unit 20 has re-logged in.

[5. Process flow on the MFP side]
FIG. 9 is a flowchart illustrating an example of processing executed by the CPU 150 of the MFP unit 10 when the user logs in to the information processing device 100. This process is realized by the CPU 150 executing a given program, for example. The contents of the process will be described with reference to FIG.

  In step S100, CPU 150 receives from server 20 the login request described as step S12 (FIG. 7).

  In step S <b> 102, CPU 150 executes login processing for the user authenticated by server unit 20. As a result, the MFP unit 10 logs in to the server unit 20 as the user and executes a job received until the user logs out as the job of the user.

  In step S104, the CPU 150 requests the server unit 20 for the count value of the user. In response to this, the CPU 250 of the server unit 20 transmits the count value of the user stored in the server-side count value DB 27 to the MFP unit 10 in step S14. The CPU 150 stores the count value received from the server unit 20 in the MFP-side count value DB 15 as the user's count value.

  In step S106, CPU 150 shifts the state of MFP unit 10 to a state of waiting for a job request from server unit 20.

  In step S108, CPU 150 determines whether or not a job request has been received from server unit 20. If it is determined that the request has been received (YES in step S108), control proceeds to step S110; In step S108, NO), the control is returned to step S106.

  In step S110, CPU 150 executes the requested job (for example, a scan job).

  In step S112, CPU 150 transmits the data generated by the execution of the job to server unit 20.

  In step S114, CPU 150 uses the attribute map to update the count value in MFP-side count value DB 15 for the user. The attribute map used in step S <b> 114 may include the same content as the attribute map used in the server unit 20. In MFP unit 10, the attribute map is stored in, for example, storage unit 160. In one example, the attribute map stipulates that the count value is decremented by “1.0” each time scan data of a document for one page is generated.

  In step S116, CPU 150 determines whether or not all jobs requested from server unit 20 have been completed in MFP unit 10. If CPU 150 determines that all jobs have been completed (YES in step S116), control proceeds to step S118, otherwise (NO in step S116), control is returned to step S110.

  In step S 118, CPU 150 transmits a job completion notification to server unit 20. In the server unit 20, the job completion notification is received in step S32 (FIG. 7). Thereafter, the CPU 150 ends the process of FIG.

[6. Processing after re-login in MFP section]
FIG. 10 is a flowchart of processing executed by the MFP unit 10 in response to a re-login request from the server unit 20 in step S34 (FIG. 7). The processing in FIG. 10 is realized by the CPU 150 executing a given program, for example. The contents of the process will be described with reference to FIG.

  In step S130, CPU 150 receives a re-login request from server unit 20.

  In step S132, the CPU 150 executes login processing for the user authenticated by the server unit 20, as in step S102.

  In step S134, the count value transmitted from server unit 20 in step S36 (FIG. 7) is received.

  In step S136, CPU 150 updates the user count value stored in MFP-side count value DB 15 with the count value received in step S134. Thereafter, the CPU 150 ends the process of FIG.

  In step S136 in FIG. 10, the count value transmitted from the server unit 20 is stored in the MFP-side count value DB 15, so that the count value is synchronized between the server unit 20 and the MFP unit 10. As a result, the processing of both the MFP unit 10 and the server unit 20 can be reflected in the count value while using the existing billing system using the count value in the MFP unit 10.

  For example, when the server unit 20 transmits the scan data after the MFP unit 10 generates the scan data, the MFP unit 10 and the server unit 20 share the count value counted down for transmission of the scan data. To do.

  In another example, after the MFP unit 10 generates scan data, when the server unit 20 deletes the scan data without transmission or storage, the MFP side count value DB 15 stores the scan data in the server side count value DB 27. By storing the count value, the MFP unit 10 eliminates the countdown due to the generation of scan data.

  In the present disclosure, the count value of each user is managed in the MFP unit 10 and the server unit 20. As an example, the count value defines the remaining amount of count allocated to each user. The server unit 20 instructs the MFP unit 10 to stop the job being executed for the user A when the count value of the user A becomes “0” by executing the process on the image data. May be. When the count value for the user A becomes “0”, the server unit 20 may notify the user of this by display on the display unit 360 or the like.

  The user A may execute a charge or the like for the server unit 20 in order to increase the count value of the user A. When the count value of the user A exceeds “0” in response to the correspondence, the server unit 20 may instruct the MFP unit 10 to resume the job that has been instructed to stop as described above.

[7. When the server unit updates the count value during job execution of the MFP unit]
FIG. 11 is a flowchart of a modification of the process of FIG. In the process of FIG. 11, if the MFP unit 10 is executing a job when the count value is updated, the server unit 20 requests the MFP unit 10 to set a synchronization request flag. The synchronization request flag is a flag for requesting login for synchronization of the count value.

  More specifically, the process shown in FIG. 11 includes the control of step S33 instead of step S32 of the process shown in FIG.

  In step S33, CPU 250 of server unit 20 requests MFP unit 10 to set a synchronization request flag. Thereafter, the CPU 250 ends the process of FIG.

  In response to the request in step S33, the CPU 150 of the MFP unit 10 sets a synchronization request flag in the MFP unit 10. In the initial state of the MFP unit 10, the synchronization request flag is reset.

  In the example in which the process of FIG. 11 is executed, if the CPU 150 determines in step S116 of the process corresponding to FIG. 9 that all jobs requested from the server unit 20 have been completed, is the synchronization request flag set? Judge whether or not. If the synchronization request flag is not set, the CPU 150 ends the process as it is.

  If it is determined that the synchronization request flag is set, the CPU 150 resets the synchronization request flag and then starts the process described with reference to FIG. In this case, the CPU 150 transmits a re-login request to the server unit 20 instead of receiving the re-login request from the server unit 20 in step S130. In response to this, the server unit 20 logs in to the MFP unit 10 again.

  When the server unit 20 logs in to the MFP unit 10 again, the server unit 20 transmits the user count value stored in the server-side count value DB 27 to the MFP unit 10.

  CPU 150 stores the count value transmitted from server unit 20 in MFP-side count value DB 15 (step S136). Thereby, the count value of the user is synchronized between the server unit 20 and the MFP unit 10.

[8. Management of count values on a server other than the server that sends the image data]
FIG. 12 is a diagram illustrating a modification of the configuration of the image processing system. In the example of FIG. 12, the image processing system 1000 includes an information processing device 100 and an external server 200 that can communicate with the information processing device 100 via a network N.

  FIG. 13 is a diagram illustrating an example of a functional configuration of the image processing system in FIG. In the example of FIG. 13, the server side count value DB 27 provided in the server unit 20 in the example of FIG. 3 is provided in the external server 200. The external server 200 includes a processor for managing the count value in the server side count value DB 27.

  The external server 200 includes a user authentication unit 201 as its function. The user authentication unit 201 is realized, for example, when the processor executes a given program. The login processing unit 21 of the server unit 20 transmits information for specifying the user to the user authentication unit 201. The user authentication unit 201 updates the count value for the user specified by the information transmitted from the login processing unit 21 in the server-side count value DB 27 and transmits the count value for the user to the MFP unit 10. .

  As indicated by an arrow A1 in FIG. 13, when a user logs in for the first time, the request processing unit 23 transmits the count value of the user to the MFP unit 10 and requests the MFP unit 10 to execute a job. The data processing unit 26 performs processing on the image data transmitted from the MFP unit 10. The upper limit counter processing unit 24 specifies a count value corresponding to the executed process. The determination unit 22 instructs the external server 200 to count down the count value of the server-side count value DB 27 by the specified value.

  As indicated by an arrow A2 in FIG. 13, when the synchronization flag is set in the server unit 20, the determination unit 22 transmits the count value in the server-side count value DB 27 to the external unit 200 to the MFP unit 10. Instruct to do. The scan counter processing unit 12 stores the count value in the server-side count value DB 27 transmitted from the external server 200 in the MFP-side count value DB 15. As a result, the count value in the server-side count value DB 27 and the count value in the MFP-side count value DB 15 are synchronized.

[9. Summary of disclosure]
The present disclosure is summarized as follows.

  As shown in FIG. 1 and the like, the image processing system (information processing device 100) includes an image processing apparatus (MFP unit 10) and an information processing apparatus (server unit 20) that can communicate with the image processing apparatus.

Information processing device
First storage means (data storage 28) for storing count information relating to the first user;
A requesting unit (request processing unit 23) that requests the image processing apparatus to generate image data in association with the first user;
Processing means (data processing unit 26) for processing image data generated in response to the request;
First update means (upper limit counter processing unit 24) for updating the count information in the first storage means in accordance with the processing by the processing means.

The image processing device
A second storage unit (MFP-side count value DB 15) for storing count information related to the first user;
Generation means (scan execution unit 13) for generating image data in response to a request;
And second update means (scan counter processing unit 12) for updating the count information related to the first user stored in the second storage means in accordance with the generation of the image data by the generation means.

  The information processing apparatus communicates with the image processing apparatus to synchronize the count information in the first storage means and the count information in the second storage means when the first update means updates the count information. Further includes synchronization means (determination unit 22).

  As shown in FIG. 13 and the like, in the image processing system, the first storage unit may be provided in a device (external server 200) different from the information processing device.

  In the present disclosure, the count information synchronization process is configured such that the count value updated based on the process on the server unit 20 side is overwritten by the count value on the MFP unit 10 side. As a result, the updated count value based on the processing on the MFP unit 10 side is ignored. This means that the count value is updated according to a policy that the image processing system is not considered to be used when the server unit 20 side process is not finally performed.

  The above process may be configured such that the count value update by the process on the MFP unit 10 side is reflected in the synchronized count value. For example, when scan data generated in the MFP unit 10 is transferred to the server unit 20, the count value on the MFP unit 10 side updated by the scan is transferred to the server unit 20, and the transferred count value is added. Thus, after the count value on the server unit 20 side is overwritten, the count value by the processing on the server unit 20 side may be updated.

  Each embodiment disclosed this time must be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims. In addition, the invention described in the embodiment and each modification is intended to be carried out independently or in combination as much as possible.

  10 MFP section, 11, 21 login processing section, 12 scan counter processing section, 13 scan execution section, 14 scan data transfer processing section, 20 server section, 22 determination section, 23 request processing section, 24 upper limit counter processing section, 25 preview Processing unit, 26 Data processing unit, 28 Data storage, 30 Operation panel, 100 Information processing device, 150, 250 CPU, 151 Image processing unit, 152 Image forming unit, 153 Image reading unit, 160, 270 Storage unit, 180, 280 Internal interface, 200 external server, 260 network communication unit, 350 control circuit, 360 display unit, 370 operation unit, 1000 image processing system.

Claims (8)

An image processing system comprising an image processing device and an information processing device capable of communicating with the image processing device,
The information processing apparatus includes:
First storage means for storing count information associated with the first user;
Requesting means for requesting the image processing apparatus to generate image data in association with the first user;
Processing means for processing the image data generated in response to the request;
First update means for updating count information in the first storage means in accordance with processing by the processing means;
Including
The image processing apparatus includes:
Second storage means for storing count information associated with the first user;
Generating means for generating image data in response to the request;
Second update means for updating count information related to the first user stored in the second storage means in accordance with the generation of image data by the generation means;
Including
The information processing apparatus includes:
An image processing system further comprising synchronization means for communicating with the image processing apparatus in order to synchronize the count information in the first storage means and the count information in the second storage means. An image processing system comprising an image processing device, an information processing device capable of communicating with the image processing device, and a server capable of communicating with the information processing device,
The server
First storage means for storing count information associated with the first user;
The information processing apparatus includes:
Requesting means for requesting the image processing apparatus to generate image data in association with the first user;
Processing means for processing the image data generated in response to the request;
First update means for updating count information in the first storage means in accordance with processing by the processing means;
Including
The image processing apparatus includes:
Second storage means for storing count information associated with the first user;
Generating means for generating image data in response to the request;
Second update means for updating count information related to the first user stored in the second storage means in accordance with the generation of image data by the generation means;
Including
The information processing apparatus includes:
An image processing system further comprising synchronization means for communicating with the image processing apparatus in order to synchronize the count information in the first storage means and the count information in the second storage means. The processing by the processing means includes at least one type of processing among image size change, image color change, and image pixel number change,
The image processing system according to claim 1, wherein the first update unit updates count information in the first storage unit in a manner according to a type of processing executed by the processing unit. .   The synchronization unit according to any one of claims 1 to 3, wherein, when the image processing apparatus is executing an image processing operation, the synchronization unit executes communication for the synchronization after the execution of the image processing operation. The image processing system according to item. When the image processing apparatus is executing an image processing operation, the synchronization unit requests the image processing apparatus to set a synchronization request flag that is a flag for the synchronization.
The image processing apparatus includes:
A setting means for setting a synchronization request flag in the image processing apparatus in response to a request for setting the synchronization request flag;
When the synchronization request flag is set, the second update unit causes the synchronization unit to synchronize the count information in the first storage unit and the count information in the second storage unit. The image processing system according to claim 1, wherein the communication is requested.   When the count information in the first storage unit reaches the upper limit assigned to the first user, the synchronization unit performs an image processing operation on the first user with respect to the image processing apparatus. The image processing system according to claim 1, wherein the stop is requested.   When the upper limit of the count information assigned to the first user is updated in the first storage unit, the synchronization unit resumes the image processing operation related to the first user with respect to the image processing apparatus. The image processing system according to claim 6, wherein:   When the image data generated in response to the request is deleted without being processed by the processing means, the synchronization means counts the information in the first storage means and the second storage means The image processing system according to claim 1, wherein the image processing system communicates with the image processing device to synchronize count information.

Images