JP2021140366A - Information processing device, information processing system, conversion method and program - Google Patents

Abstract

To provide a device, a system, a method and a program, capable of easily transferring setting information.SOLUTION: An information processing device is a device for converting setting information, including: obtainment means for obtaining setting information from a first apparatus; processing means for using correspondence information in which setting items are associated one another to output setting values included in the obtained setting information in association with the setting items of a second apparatus; and conversion means for using registration information in which the setting items and the setting values for each apparatus are registered to convert the output setting values.SELECTED DRAWING: Figure 4

Description

The present invention relates to devices, systems, methods and programs that convert setting information.

When connecting and using a plurality of devices to the network, it is necessary to make settings for each device, and performing this one by one is a laborious task. For example, in an office or the like, a plurality of multifunction devices are installed, but not all of them are the same model. Since the format of the setting information differs depending on the model, it is not possible to transfer the setting information of one multifunction device to another multifunction device and apply the setting information to the other multifunction device.

Therefore, the setting items having the same definition between the setting information of the setting source device and the setting information of the setting destination device are extracted, and for each extracted setting item, the corresponding setting item of the setting information of the setting source device is extracted. A technique has been proposed in which the set value of is applied to the set destination device (see, for example, Patent Document 1).

In the conventional technology, if the definition is the same setting item, it is assumed that the meaning of the setting value does not differ between the models. However, if the manufacturers that provide the devices are different, the meanings of the set values are generally different even if the meanings of the setting items are the same, and in the above-mentioned conventional technology, the setting information can be easily transferred. There was a problem that it could not be done.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a device, a system, a method, and a program capable of easily transferring setting information.

In order to solve the above-mentioned problems and achieve the object, the present invention is an information processing device that converts setting information.
An acquisition method for acquiring setting information from the first device,
A processing means for outputting the setting value included in the acquired setting information in association with the setting item of the second device by using the correspondence information in which the setting items are associated with each other.
Provided is an information processing apparatus including a conversion means for converting an output set value by using the registered information in which the setting items and the set values of each device are registered.

According to the present invention, the setting information can be easily transferred.

The figure which showed the configuration example of the information processing system which concerns on this embodiment. The figure which showed an example of the hardware configuration of the management server. The figure which showed an example of the hardware composition of another company's machine. The block diagram which showed the 1st example of the functional structure of management server. A flowchart showing the flow of the entire process executed by the information processing system. The figure which showed an example of the device information of another company's machine. The figure which showed an example of the acquisition request of setting data. The figure which showed an example of the setting data acquired from the other company's machine. The figure which showed an example of the setting item conversion table. A flowchart showing the flow of processing for outputting the setting data of another company's machine in the format of the setting data of the company's machine. The figure which showed an example of the format of the output setting data. The figure which showed an example of the setting value conversion table. A flowchart showing the flow of processing for converting a set value from another company's machine to its own machine. The figure which showed an example of the setting data after conversion. The figure which showed another example of the setting data before and after conversion. The figure which showed an example of the management table which manages the setting data. The block diagram which showed the 2nd example of the functional structure of the management server. A flowchart showing the flow of semi-automatic creation of the setting value conversion table. The figure which showed an example of the setting value conversion table before semi-automatic creation. The figure which showed an example of the setting data acquired in the semi-automatic creation. The figure which showed an example of the setting value conversion table in the process of semi-automatic creation. The block diagram which showed the 3rd example of the functional structure of the management server. The figure which showed an example of the difference tolerance setting table. A flowchart showing the flow of semi-automatic creation of a setting value conversion table using a difference tolerance setting table. The figure which showed an example of the setting data acquired in the semi-automatic creation. The figure which showed an example of the setting value conversion table in the process of semi-automatic creation. The figure which showed another example of the setting data acquired from the other company's machine. The figure explaining the method of simple comparison of a set value. The figure explaining the 1st method of inserting a blank character and comparing a set value. The figure which showed the result of simple comparison of another setting value. The figure which showed the result of having applied the 1st method to another set value and compared. The figure explaining the 2nd method of inserting a blank character and comparing a set value.

FIG. 1 is a diagram showing a configuration example of an information processing system according to the present embodiment. The information processing system is a system that imports (imports) the setting information set in one device into one or more other devices and realizes the transfer of the setting information. The information processing system includes an information processing device for realizing the transfer of setting information.

The device having the setting information and the device for importing the setting information may be any device as long as it requires the setting of the setting information and has a communication function. Devices include, for example, image forming devices such as printers, MFPs (Multi-Function Peripheral), copiers, and FAX devices, PJs (Projectors), and IWBs (Interactive White Boards: electronic whiteboard functions that enable mutual communication. Whiteboards), output devices such as digital signage, HUD (Head Up Display) devices, industrial machines, image pickup devices, sound collectors, medical devices, network home appliances, automobiles, and the like. The device may be a notebook PC (Personal Computer), a smartphone, a tablet terminal, a game machine, a PDA (Personal Digital Assistant), a wearable PC, a desktop PC, or the like.

When one device and one or more other devices are of the same manufacturer and of the same model, the contents of the setting information are exactly the same, so that they can be transferred as they are by copying or the like. On the other hand, if one device and one or more other devices are made by different manufacturers, or even if they are made by the same manufacturer, if the models are different or the versions are different, the copy method cannot be used for migration.

Therefore, the information processing device converts the setting information of one device into the setting information for the other one or more devices and provides the setting information to the other one or more devices. The information processing system may be configured to include one or more other devices in addition to the information processing device, and may be further configured to include one device. Further, the information processing system may be configured to provide an information processing device separately from one device and one or more other devices, or one of one device or one or more other devices. In addition, it may be configured to implement the functions of the information processing device.

Hereinafter, the information processing device will be described in detail as a management server, and the device will be described in detail as an image forming device. The setting information (setting data) includes setting items and setting values, and examples of the setting items of the image forming apparatus include single-sided / double-sided setting and aggregate setting for setting how many pages are printed on one sheet of paper. ..

Item names for single-sided / double-sided settings differ depending on the manufacturer, and even for the same manufacturer, they differ depending on the version. The value (setting value) assigned to each item also differs depending on the manufacturer and version. This also applies to the aggregation setting. Therefore, the setting data will be converted and transferred from the image forming apparatus (other company's machine) of another company to the image forming apparatus (in-house machine) of the company in detail.

In FIG. 1, an information processing system is configured by connecting a management server 11, a third-party machine 12, and an in-house machine 13 to a network 10. The management server 11 requests the other company's machine 12 to acquire the setting data via the network 10, and acquires the setting data from the other company's machine 12.

The management server 11 converts the acquired setting data into the setting data for the company's machine 13, and transmits the converted setting data to the company's machine 13 via the network 10. When transmitting the converted setting data, the management server 11 instructs its own machine 13 to set the setting data. The in-house machine 13 receives the instruction and sets the received setting data. This completes the migration of the setting data.

When a plurality of in-house machines 13 exist, the management server 11 transmits the converted setting data to the plurality of in-house machines 13. As a result, the setting data can be easily transferred to a plurality of devices.

The network 10 may be either a wired network or a wireless network, may be a LAN (Local Area Network), or may be a WAN (Wide Area Network).

FIG. 2 is a diagram showing an example of the hardware configuration of the management server 11. The management server 11 includes a CPU 20, a ROM 21, a RAM 22, an HD23, an HDD controller 24, a display I / F26, an external device connection I / F27, a network I / F28, and a bus line, as in a general PC. It includes 29, a keyboard 30, a mouse 31, a DVD-RW (Digital Versatile Disk Rewritable) drive 32, and a media I / F 33. Here, the display 25 is connected to the management server 11, and the display 25 is not included in the management server 11, but it may be included.

The CPU 20 controls the operation of the entire management server 11. The ROM 21 stores a program used to drive the CPU 20 such as an IPL (Internet Printer Language). The RAM 22 provides a work area for the CPU 20. The HD23 stores various programs and various data. The HDD controller 24 controls reading and writing of various data to the HD 23 according to the control of the CPU 20.

The display 25 displays various information such as cursors, menus, windows, characters, and images. The display I / F 26 is an interface for connecting the display 25 to the management server 11 and controlling the display of the display 25. The external device connection I / F27 is an interface for connecting various external devices. The external device is, for example, a USB memory, a printer, or the like. The network I / F 28 is an interface for communicating via the network 10. The bus line 29 is an address bus or a data bus for electrically connecting each component such as the CPU 20.

The keyboard 30 is an input means including a plurality of keys for inputting characters, numerical values, various instructions, and the like. The mouse 31 is an input means for selecting and executing various instructions, selecting a processing target, moving a cursor, and the like. The DVD-RW drive 32 controls reading and writing of various data to the DVD-RW 34, which is one of the removable recording media. Here, the recording medium is DVD-RW, but the recording medium is not limited to DVD-RW, and may be CD-R, CD-RW, DVD-R, or the like. The media I / F 33 controls reading and writing of data to a recording medium 35 such as a flash memory.

FIG. 3 is a diagram showing an example of the hardware configuration of the other company's machine 12. Here, another company's machine 12 will be described as an MFP. Since the in-house machine 13 also has the same MFP and has the same configuration, the description of the in-house machine 13 will be omitted.

The other company's machine 12 includes a controller 40, a short-range communication circuit 41, an engine control unit 42, an operation panel 43, and a network I / F 44.

The controller 40 includes a CPU 50, which is a main part of a computer, a system memory (MEM-P) 51, a north bridge (NB) 52, a south bridge (SB) 53, an ASIC (Application Specific Integrated Circuit) 54, and a local controller 40. It includes a memory (MEM-C) 55, an HDD controller 56, and an HD (Hard Disk) 57. The NB 52 and the ASIC 54 are connected by an AGP (Accelerated Graphics) bus 58.

The CPU 50 functions as a control unit that controls the entire MFP. The NB 52 is a bridge that connects the CPU 50 and the MEM-P51, SB53, and AGP bus 58, and includes a memory controller that controls reading and writing to the MEM-P51, a PCI (Peripheral Component Interconnect) master, and an AGP target.

The MEM-P51 is composed of a ROM 51a for storing programs and data for realizing each function of the controller 40, and a RAM 51b used for developing programs and data, drawing at the time of printing, and the like. The program stored in the RAM 51b is recorded on a computer-readable recording medium such as a CD-ROM, CD-R, DVD, USB (Universal Serial Bus) memory, or SD card in an installable or executable format file. May be configured to provide.

The SB53 is a bridge for connecting the NB 52 to a PCI device and peripheral devices. The ASIC 54 is an IC (Integrated Circuit) for image processing applications that has hardware elements for image processing, and has a role of a bridge that connects the MEM-C55, the HDD controller 56, the AGP bus 58, and the PCI bus 59, respectively. The ASIC 54 includes a PCI target, an AGP master, an arbiter (ARB) that forms the core of the ASIC 54, a memory controller that controls the MEM-C55, and a plurality of DMACs (Direct Memory Access Controllers) that rotate image data by hardware logic or the like. ), And a PCI unit that transfers data between the scanner unit 60 and the printer unit 61 via the PCI bus 59. An interface of USB or IEEE (Institute of Electrical and Electronics) 1394 may be connected to the ASIC 54.

The MEM-C55 is a local memory used as a copy image buffer or a code buffer. The HD57 is a storage for storing image data, font data used at the time of printing, forms, and the like. The HDD controller 56 controls reading and writing of data to the HD 57 according to the control of the CPU 50. The AGP bus 58 is a bus interface for a graphic accelerator card for speeding up graphic processing, and speeds up the graphic accelerator card by directly accessing the MEM-P51 with high throughput.

The short-range communication circuit 41 is a circuit that performs short-range wireless communication by NFC (Near Field Communication), Bluetooth (registered trademark), or the like. The short-range communication circuit 41 is provided with a short-range communication antenna 41a. The engine control unit 42 is composed of a scanner unit 60 and a printer unit 61, and controls a scanner and a printer included in another company's machine 12.

The operation panel 43 displays a current setting value, a selection screen, etc., and receives a panel display unit 43a such as a touch panel that accepts input from a user, and a numeric keypad or a copy that accepts setting values of conditions related to image formation such as density setting conditions. It is composed of an operation button 43b such as a start key that receives a start instruction.

The network I / F44 is an interface for communicating via the network 10. The short-range communication circuit 41 and the network I / F 44 are electrically connected to the ASIC 54 via the PCI bus 59.

The controller 40 controls the entire other company's machine 12, and for example, the scanner function, the document box function, the copy function, the printer function, and the facsimile function are sequentially switched and selected by the application switching keys of the drawing, communication, and operation panel 43. To enable. When each function is selected, the other company's machine 12 is in a mode corresponding to each function.

Next, the functional configuration of the management server 11 will be described with reference to FIG. FIG. 4 is a block diagram showing a first example of the functional configuration of the management server 11. Each functional unit is realized by the CPU reading the program stored in the HD via the HDD controller, expanding it on the RAM, and executing the program. Each functional unit is realized by devices such as ASIC (Application Specific Integrated Circuit), DSP (Digital Signal Processor), FPGA (Field Programmable Gate Array) and conventional circuit modules designed to execute each function. You may.

The management server 11 includes an acquisition unit 70, a storage unit 71, a processing unit 72, a conversion unit 73, and a transmission unit 74.

The acquisition unit 70 acquires the setting data set in the other company's machine 12 from the other company's machine 12. The acquisition unit 70 acquires the device information 75 of the other company's machine 12 stored in the storage unit 71, and requests the other company's machine 12 to acquire the setting data using the acquired device information 75. The device information 75 of the other company's machine 12 includes an IP (Internet Protocol) address for accessing the other company's machine 12 via the network 10, a device name, a manufacturer name, a method of acquiring setting data, and the like.

In addition to the device information 75 of the other company's machine 12, the storage unit 71 transfers the setting data of the other company's machine 12 acquired by the acquisition unit 70 to the own machine 13, so that the corresponding information for converting the setting data for the own machine 13 is obtained. And memorize registration information. Correspondence information is information in which setting items are associated with each other, and registration information is information in which setting items and setting values of each device are registered. Hereinafter, the correspondence information will be referred to as the setting item conversion table 76, and the registration information will be described as the setting value conversion table 77. Here, the format for conversion using a table (table format) is described, but the format is not limited to the table format.

Further, the storage unit 71 stores the setting data 78 for the company machine 13 obtained by conversion until it is transmitted to the company machine 13. It can be transmitted to the in-house machine 13 in response to an instruction from the system administrator.

Using the setting item conversion table 76, the processing unit 72 converts the setting items included in the setting data of the other company's machine 12 acquired by the acquisition unit 70 into the setting items included in the setting data of the company's machine 13, and converts the setting items into the setting data of the other company's machine 13. The setting values corresponding to the above setting items of 12 are output in association with the converted setting items of the in-house machine 13. That is, the processing unit 72 outputs the setting data of the other company's machine 12 in the data format (format) of the setting data of the company's machine 13.

The conversion unit 73 uses the setting value conversion table 77 to convert the setting value of the setting data output by the processing unit 72 into the setting value of the company's own machine 13. Since only the setting items are converted into the setting items of the own machine 13 in the processing unit 72, the setting values corresponding to each setting item are converted into the setting values of the own machine 13 by the conversion unit 73. The conversion unit 73 stores the setting data 78 converted to the storage unit 71.

The transmission unit 74 transmits the setting data 78 stored in the storage unit 71 to the in-house machine 13, and transfers the setting data to the in-house machine 13.

The management server 11 can include an editorial unit 79, if necessary. The editorial unit 79 receives information or edited contents for creating the setting item conversion table and the set value conversion table, creates each table, or reads the table from the storage unit 71, and edits the contents of the table. The editorial unit 79 stores the created table in the storage unit 71, overwrites the edited table in the storage unit 71, and updates the table.

FIG. 5 is a flowchart showing the flow of the entire process executed by the information processing system. The process of transferring the setting data of the other company's machine 12 to the company's machine 13 is started from step 100. In step 101, the acquisition unit 70 communicates with the other company's machine 12 and acquires the setting data from the other company's machine 12. The other company's machine 12 implements, for example, a Web API (Application Programming Interface), and when a request for acquisition of setting data is transmitted to the Web API using HTTP (Hypertext Transfer Protocol), the setting data is transmitted as a response. .. Therefore, the acquisition unit 70 transmits a setting data acquisition request to the Web API of the other company's machine 12, and acquires the setting data from the Web API. Here, the configuration for acquiring the setting data using HTTP is illustrated, but the present invention is not limited to this, and the setting data may be acquired using SNMP (Simple Network Management Protocol) or the like.

In step 102, the processing unit 72 uses the setting item conversion table 76 to output the setting values of the other company's machine 12 in the format of the setting data of the company's machine 13. In step 103, the conversion unit 73 converts the set value of the other company's machine 12 into the set value of the own machine 13 by using the set value conversion table 77.

In step 104, the transmission unit 74 imports the converted setting data 78 of the other company's machine 12 into the company's machine 13, and completes the migration in step 105.

FIG. 6 is a diagram showing an example of the device information 75 of the other company's machine 12 used for transmitting the acquisition request to the other company's machine 12 in step 101. The device information 75 includes a device serial number, a device IP address, a device manufacturer name, and a URL (Uniform Resource Locator) as a setting value acquisition method, which are examples of information for identifying the device. The information for identifying the device may be a device name, a MAC (Media Access Control) address, or the like.

FIG. 7 is a diagram showing an example of a request for acquiring setting data to be transmitted to the other company's machine 12 in step 101. The acquisition request is generated using the device information 75 shown in FIG. The acquisition request shown in FIG. 7 specifies an IP address and requests setting data from another company's machine 12 having the device serial number "AB0001".

FIG. 8 is a diagram showing an example of setting data acquired from another company's machine 12. The setting data includes a setting item name indicating a setting item and a setting value set for the setting item. Here, "print.double_sided" indicating the double-sided setting and "print.pages_per_sheet" indicating the aggregation setting are set as setting items, and "2" is set as their setting value.

FIG. 9 is a diagram showing an example of the setting item conversion table 76 used in step 102. The setting item conversion table 76 is a table in which the setting items of the other company's machine 12 and the setting items of the company's machine 13 are associated with each other. The table shown in FIG. 9 includes a setting item name as a setting item of the other company's machine 12, and includes a setting item ID as a setting item of the company's machine 13. Further, the table shown in FIG. 9 includes a maker name indicating a maker of another company's machine 12.

FIG. 10 is a flowchart showing details of a process of outputting the setting data of the other company's machine 12 in step 102 of FIG. 5 in the format of the setting data of the company's machine 13. After acquiring the setting data of the other company's machine 12 in step 101 of FIG. 5, this process is started from step 200. In step 201, the manufacturer name of the other company's machine 12 is acquired from the device information 75 of the other company's machine 12.

In step 202, one line of the acquired setting data of the other company's machine 12 is read. In step 203, the setting item conversion table 76 is referred to, and it is confirmed whether or not there is a record in the setting item conversion table that matches the read setting item name and the acquired manufacturer name. If it exists, the process proceeds to step 204, and the setting item ID of the company's own machine 13 corresponding to the setting item name of the other company's machine 12 is acquired from the setting item conversion table 76. In step 205, the setting item name of the other company's machine 12 in the setting data is converted into the acquired setting item ID of the company's machine 13. The setting item ID and the set value are output according to the format of the setting data of the in-house machine 13. Then, the process proceeds to step 206. If it is confirmed in step 203 that it does not exist, the process directly proceeds to step 206.

In step 206, it is confirmed whether or not all the lines of the acquired setting data have been read. If the reading of all lines is not completed, the process returns to step 202 and the next line is read. On the other hand, when the reading of all the rows is completed, the process proceeds to step 207 and the process ends.

FIG. 11 is a diagram showing an example of the format of the setting data output by the process shown in FIG. The setting data shown in FIG. 7 includes the setting item name of the other company's machine 12 and the setting value of the other company's machine 12 corresponding to the setting item name, and the setting item name is in-house using the table shown in FIG. It is converted into the setting item ID of the machine 13. In the example shown in FIG. 11, "print.double_sided" is converted to "S001" and "print.pages_per_sheet" is converted to "S002". The set value is the same as the set value of the other company's machine 12.

FIG. 12 is a diagram showing an example of the set value conversion table 77 used in step 103 of FIG. The setting value conversion table 77 is a table in which the setting items of each device and the setting values are associated with each other. The table shown in FIG. 12 includes a setting item ID and a setting item name as setting items, and includes a value ID, a meaning of the value, a value of an in-house machine, and a value of another company's machine as setting values. The table may contain only the setting item ID, the value of the company's machine, and the value of another company's machine, but by including the setting item name and the meaning of the value, what the setting item ID indicates and what the value is. It becomes easier to understand what it means.

The value of the other company's machine in the set value conversion table 77 is the value of the other company's machine manufacturer of the conversion source, and is referred to when converting the value of the other company's machine to the value of the company's own machine. In the example shown in FIG. 12, the set values of the manufacturer A and the manufacturer B are registered as the values of the other company's machine.

FIG. 13 is a flowchart showing the details of the process of converting the set value from the other company's machine 12 to the company's machine 13 in step 103 of FIG. After outputting the setting data in step 102 of FIG. 5, this process is started from step 300. In step 301, the manufacturer name of the other company's machine 12 is acquired from the device information 75 of the other company's machine 12.

In step 302, one line of the acquired setting data is read. In step 303, it is confirmed whether or not the read setting item ID and the record corresponding to the setting value exist in the setting value conversion table 77. At this time, the matching item is searched for in the column of the table that matches the acquired manufacturer name.

If it exists in step 303, the process proceeds to step 304, and the set value of the in-house machine 13 corresponding to the set value of the other company's machine 12 is acquired from the set value conversion table 77. In step 305, the setting value of the other company's machine 12 in the setting data is rewritten with the acquired setting value of the company's machine 13. Then, the process proceeds to step 306. If it is confirmed in step 303 that it does not exist, the process directly proceeds to step 306.

In step 306, it is confirmed whether or not all the rows of the acquired setting data have been read. If the reading of all lines is not completed, the process returns to step 302 and the next line is read. On the other hand, when the reading of all the rows is completed, the process proceeds to step 307 and the process is terminated.

FIG. 14 is a diagram showing an example of the setting data 78 after being converted by the process shown in FIG. The setting data before conversion is the data having the contents shown in FIG. Before the conversion, both the setting item IDs "S001" and "S002" had the set value "2", but after the conversion, they are converted to the set value "1".

The setting data before and after the conversion shown in FIGS. 11 and 14 exemplify the case where the other company's machine 12 is the manufacturer A shown in FIG. The setting items are double-sided printing "S001" and aggregate printing "S002" that prints two pages on one sheet of paper. FIG. 12 also includes the set values when the other company's machine 12 is the manufacturer B. Therefore, the setting data before and after the conversion when the other company's machine 12 is the manufacturer B will be described with reference to FIGS. 15A and 15B.

In FIG. 15A, the same setting items "S001" and "S002" are set, and since the manufacturer B, the set value is set to "20". Since FIG. 15B is converted to the set value of the in-house machine 13, it is converted to the set value “1” as in FIG.

The converted setting data 78 is the setting data in the format of the in-house machine 13, is stored in the storage unit 71, and is managed by the management table. FIG. 16 is a diagram showing an example of a management table that manages setting data. The management table manages the setting data information in association with the device serial number and the manufacturer name, which are information for identifying the device. The setting data information is information indicating a storage location of the setting data.

When the transmission unit 74 transmits the setting data of the other company's machine 12 converted into the setting data format of the own machine 13 to the own machine 13, the information of the setting data is based on the device serial number and the manufacturer name of the own machine 13. Is searched, and the setting data is read and acquired from the storage unit 71 using the information of the searched setting data. Then, the transmission unit 74 transmits the acquired setting data 78 to the company's own machine 13 by using the device information 75 stored and managed in the storage unit 71.

In the examples described so far, the setting item conversion table 76 shown in FIG. 9 and the setting value conversion table 77 shown in FIG. 12 are created in advance by using the editorial unit 79, edited as necessary, and stored. It is stored in the part 71. These creation and editing work (preparation work) are performed before the setting data migration work.

However, the preparation work of these tables is a time-consuming and labor-intensive work for the system administrator because the number of setting items is large when the device to be set is an image device such as an image forming device. If even a part of the table preparation work can be performed automatically, the burden on the system administrator can be reduced.

FIG. 17 is a block diagram showing a second example of the functional configuration of the management server 11. The management server 11 includes an acquisition unit 70, a storage unit 71, a processing unit 72, a conversion unit 73, a transmission unit 74, and an editorial unit 79, as in the configuration shown in FIG. In the example shown in FIG. 17, the management server 11 further includes a creation unit 80 that automatically performs a part of the table preparation work. Here, only the parts different from the configuration shown in FIG. 4 will be described.

The creation unit 80 automatically creates only the setting items that take a character string as the setting value. Specifically, the creation unit 80 automatically creates a part of the set value conversion table 77. Since only a part of the setting value conversion table can be automatically created, this process is hereinafter referred to as a semi-automatic creation process or simply a semi-automatic creation process.

The system administrator displays a Web page for system management on the display 25, and gives an instruction to start processing from the Web page. The creation unit 80 receives the instruction and carries out semi-automatic creation. The semi-automatically created table is stored in the storage unit 71 and used in the setting data migration work.

FIG. 18 is a flowchart showing the flow of semi-automatic creation of the setting value conversion table using the creation unit 80. The process is started from step 400 in response to the instruction from the system administrator. At the start of this process, the setting item conversion table is created and registered in advance, and the setting value conversion table is also created and registered except for a part.

The semi-automatically created table is a table in which only the set value of the other company's machine 12 has a blank column. FIG. 19 shows an example of the set value conversion table 77 before semi-automatic creation. In the set value conversion table 77, as in FIG. 12, information is set in the setting item ID, the setting item name, the value ID, the meaning of the value, and the value (setting value) column of the in-house machine 13, and the value of the manufacturer C is set. Only the column to be set is blank. In the semi-automatic creation, the value of maker C is created and set in the blank column.

In step 401, a request for acquiring setting data is transmitted to the Web API of the other company's machine 12, and the setting data is acquired from the Web API. FIG. 20 shows an example of the setting data acquired in the semi-automatic creation. In the example shown in FIG. 20, the setting value "single_sided" is associated with the setting item "print.double_sided", and the setting value "2in1" is associated with the setting item "print.pages_per_sheet".

In step 402, one setting item is selected from the setting items of the acquired setting data. The setting items can be selected in order from the first line, for example. In step 403, the setting item conversion table 76 is referred to, and the setting item ID of the company's own machine 13 corresponding to the setting item of the other company's machine 12 is acquired. Here, for example, it is assumed that "S001" is acquired.

In step 404, the setting value conversion table 77 is referred to, and all the setting values that can be obtained by the acquired setting item ID of the company machine 13 are acquired. When the setting value conversion table 77 shown in FIG. 19 is referred to, the possible setting values of the setting item ID “S001” are “single_sided” corresponding to the value IDs “V001” and “V002” of the setting item name “double-sided setting”. , "Double_sided".

In step 405, it is determined whether or not the acquired set values match the set values of the other company's machine 12. In the example shown in FIG. 19, the same setting value “single_sided” exists. Therefore, the process proceeds to step 406, and as shown in FIG. 21, "single_sided" is set in the column of the value of the manufacturer C in the blank, and the blank is filled.

In step 407, it is confirmed whether or not there is an unselected setting item among the setting items of the acquired setting data. If it exists, the process returns to step 402 and one of the unselected setting items is selected. On the other hand, if it does not exist, the process proceeds to step 408 and the semi-automatic creation is completed.

In the second example described with reference to FIGS. 17 to 21, semi-automatic creation will be described, and when the character strings indicating the setting values of the other company's machine 12 and the company's machine 13 are exactly the same, the matching character string is used. It is set as a set value of the company's machine 13. However, the character strings of the set values do not always exactly match between the other company's machine 12 and the company's machine 13. Settings with the same meaning are not exact matches, but are often composed of similar strings. Therefore, a configuration or process in which semi-automatic creation is performed by regarding set values that are not exact matches but have high consistency as the same will be described as a third example.

FIG. 22 is a block diagram showing a third example of the functional configuration of the management server 11. Similar to the configuration shown in FIG. 17, the management server 11 includes an acquisition unit 70, a storage unit 71, a processing unit 72, a conversion unit 73, a transmission unit 74, an editorial unit 79, and a creation unit 80. .. In the example shown in FIG. 22, the difference tolerance setting table 81 is further stored in the storage unit 71. Here, only the part different from the configuration shown in FIG. 17 will be described.

As shown in FIG. 23, the difference tolerance setting table 81 manages the difference tolerance (%) in association with the setting item ID and the setting item name. The difference tolerance is a value (threshold value) indicating a criterion of what percentage or more of the same characters are considered to be the same when the character strings are compared character by character. In the example shown in FIG. 23, the difference tolerance is set to 70%, and if they match 70% or more, it is determined that they are the same.

Explaining with a specific example, for example, assuming that the setting value of the double-sided setting of the manufacturer C is "single-sided" and the setting value conversion table 77 has the contents shown in FIG. 19, the setting value conversion table 77 There are two setting values for double-sided setting, "single_sided" and "double_sided".

The setting value "single-sided" of the manufacturer C and the setting value "single_sided" of the setting value conversion table 77 are from the first to the sixth character of "single" and "sided", and from the eighth character to the last 12th character. The characters at each position of are matched by a total of 11 characters, and only the 7th character "-" and "_" are different. Therefore, the degree of agreement is calculated as 11/12 × 100 = 91.7%.

The setting value "single-sided" of the manufacturer C and the setting value "double_sided" of the setting value conversion table 77 are the 5th, 6th, and 8th to the last 12 characters of "le" and "sided". A total of 7 characters up to are matched. Therefore, the degree of agreement is calculated as 7/12 × 100 = 58.3%.

In this case, since the difference tolerance of the set values in the double-sided setting is 70%, the former "single-sided" and "single_sided" are 91.7%> 70%, and it is determined that they match. On the other hand, the latter "single-sided" and "double_sided" are 58.3% <70%, and it is determined that they do not match.

As a result of these, as the value of the manufacturer C corresponding to the value "single_sided" of the in-house machine 13, "single-sided" determined to match is set in the blank column.

FIG. 24 is a flowchart showing the flow of semi-automatic creation of the set value conversion table using the difference tolerance setting table 81. The process is started from step 500 in response to the instruction from the system administrator. At the start of this process, the setting item conversion table is created and registered in advance, and the setting value conversion table is also created and registered except for a part.

In step 501, a request for acquiring setting data is transmitted to the Web API of the other company's machine 12, and the setting data is acquired from the Web API. FIG. 25 shows an example of the setting data acquired in the semi-automatic creation. In the example shown in FIG. 25, the setting value "single-sided" is associated with the setting item "print.double_sided", and the setting value "2in1" is associated with the setting item "print.pages_per_sheet". There is.

In step 502, one setting item is selected from the setting items of the acquired setting data. The setting items can be selected in order from the first line, for example. In step 503, the setting item conversion table 76 is referred to, and the setting item ID of the company's own machine 13 corresponding to the setting item of the other company's machine 12 is acquired. Here, for example, it is assumed that "S001" is acquired.

In step 504, the setting value conversion table 77 is referred to, and all the setting values that can be obtained by the acquired setting item ID of the company machine 13 are acquired. When the setting value conversion table 77 shown in FIG. 19 is referred to, the possible setting values of the setting item ID “S001” are “single_sided” corresponding to the value IDs “V001” and “V002” of the setting item name “double-sided setting”. , "Double_sided".

In step 505, it is determined whether or not the acquired set value has a difference within the allowable range from the set value “single-sided” of the other company's machine 12. In the example shown in FIG. 19, as a set value within the allowable range, there is "single_sided" which is determined to match with a difference tolerance of 70% or more. Therefore, the process proceeds to step 506, and as shown in FIG. 26, “single-sided” is set in the column of the value of the maker C in the blank, and the blank is filled.

In step 507, it is confirmed whether or not there is an unselected setting item among the setting items of the acquired setting data. If it exists, the process returns to step 502 and one of the unselected setting items is selected. On the other hand, if it does not exist, the process proceeds to step 508 and the semi-automatic creation is completed.

Here, it is assumed that the setting data shown in FIG. 27 is acquired as the setting data of the other company's machine 12. In the setting data shown in FIG. 27, the setting value of the double-sided setting of the manufacturer C is "Single Sided". The set value of the in-house machine 13 is the value set in the set value conversion table 77 shown in FIG.

When the set value "Single Sided" of the other company's machine 12 is compared with the value "single_sided" of the company's machine 13, it can be seen that both character strings have essentially a high degree of agreement when visually recognized by the human eye.

However, in the method of comparing characters one by one from the beginning by the above method, as shown in FIG. 28, the sixth character from the beginning matches, but the seventh and subsequent characters do not match. Then, since only 6 characters of the character string indicating the set value of the other company's machine 12 match with the character string (12 characters in total) indicating the value of the company's machine 13, the degree of matching is 6/12 × 100 = 50%. Only. This results in inconsistencies, even though the degree of agreement is essentially high.

Since this problem is caused by the different rules of how to connect English words, we will introduce the method of inserting blank characters as explained below. There are two methods for inserting a blank character, regarding the position where the blank character is inserted.

The first method is to insert a blank character at the boundary between the matching part and the non-matching part when the characters constituting the character string match two or more consecutively and then do not match two or more consecutively. , A method of recalculating the degree of agreement.

A simple comparison between the value "single_sided" of the in-house machine 13 and the set value "Single Sided" of the other company's machine 12 gives only a 50% degree of agreement as shown in FIG. 28. From the first character to the sixth character, two or more characters are consecutively matched, and after the seventh character, two or more characters are consecutively unmatched. Therefore, as shown in FIG. 29, the boundary is set between the 6th character "e" and the 7th character "S", a blank character is inserted at the boundary, and the degree of matching is recalculated. Then, 11 out of 12 characters match, and the degree of matching improves to 91.7%. If the degree of matching is improved by recalculation, the improved degree of matching is adopted. In this example, since the improved degree of agreement is 70% or more of the difference tolerance, it is determined to be a match.

A simple comparison between the value "single_sided" of the in-house machine 13 and the set value "Double Sided" of the other company's machine 12 shows that there are only two characters, "l" and the sixth character "e", as shown in FIG. It does not match. Therefore, only 16.7% of agreement can be obtained. When the first method is applied and a blank character is inserted between "le" that matches two or more consecutively and "Sided" that does not match two or more consecutively, seven characters are inserted as shown in FIG. Are in agreement, and the degree of agreement is improved to 58.3%.

The second method is that if the characters do not match two or more consecutively and then match two or more consecutively, a blank character is inserted at the boundary between the mismatched part and the matching part, and the degree of matching is re-matched. It is a method of calculation.

When the second method is used, as shown in FIG. 32, the boundary is set between "Doub", which is two or more consecutive mismatches, and "le", which is two or more consecutive matches. When a blank character is inserted, the five characters match, and the degree of matching becomes 41.7%.

The set value "Double Sided" of the other company's machine 12 is less than 70% of the difference tolerance even if the value has the highest degree of matching (58.3%), and it is determined that the value does not match the value "single_sided" of the company's machine 13. From the above, "Single Sided" determined to match is set as the value of the manufacturer C corresponding to the value "single_sided" of the in-house machine 13.

In the above method, the judgment is made without distinguishing between uppercase and lowercase letters, but it is also possible to distinguish between them by setting. The typeface can be judged without distinction, but it may also be judged by distinction according to the setting.

As described above, the setting data in a desired format can be converted, so that the setting data can be easily transferred. In addition, since a part of the setting value conversion table used for converting the setting data can be automatically created, the time and effort for the system administrator to create and prepare the table can be reduced.

Although the present invention has been described with the above-described embodiment as a program for causing a computer such as an information processing device, an information processing system, a conversion method, and an information processing device to execute the present invention, the present invention is limited to the above-described embodiment. It is not something that is done. Therefore, other embodiments, additions, changes, deletions, etc. can be made within the range that can be conceived by those skilled in the art, and as long as the actions and effects of the present invention are exhibited in any of the embodiments, the present invention It is included in the range.

Therefore, it is possible to provide a method executed by the information processing system, a recording medium on which the program is recorded, a server device that provides the program via a network, and the like.

10 ... Network 11 ... Management server 12 ... Other company's machine 13 ... Own machine 20 ... CPU
21 ... ROM
22 ... RAM
23 ... HD
24 ... HDD controller 25 ... Display 26 ... Display I / F
27 ... External device connection I / F
28 ... Network I / F
29 ... Bus line 30 ... Keyboard 31 ... Mouse 32 ... DVD-RW drive 33 ... Media I / F
34 ... DVD-RW
35 ... Recording media 40 ... Controller 41 ... Short-range communication circuit 41a ... Short-range communication antenna 42 ... Engine control unit 43 ... Operation panel 43a ... Panel display unit 43b ... Operation button 44 ... Network I / F
50 ... CPU
51 ... MEM-P
51a ... ROM
51b ... RAM
52 ... NB
53 ... SB
54 ... ASIC
55 ... MEM-C
56 ... HDD controller 57 ... HD
58 ... AGP bus 59 ... PCI bus 60 ... Scanner unit 61 ... Printer unit 70 ... Acquisition unit 71 ... Storage unit 72 ... Processing unit 73 ... Conversion unit 74 ... Transmission unit 75 ... Device information 76 ... Setting item conversion table 77 ... Setting value Conversion table 78 ... Setting data 79 ... Editing unit 80 ... Creating unit 81 ... Difference tolerance setting table

JP-A-2017-216530

Claims (11)

An information processing device that converts setting information
An acquisition method for acquiring setting information from the first device,
A processing means for outputting the set value included in the acquired setting information in association with the setting item of the second device by using the correspondence information in which the setting items are associated with each other.
An information processing device including a conversion means for converting the output set value by using the registered information in which the setting item and the set value of each device are registered. The first aspect of the present invention, wherein the conversion means rewrites the setting value output in association with the setting item of the second device to a setting value corresponding to the setting item of the second device in the registration information. Information processing equipment. The registration information is associated with the setting items and the setting values of the respective devices, and the setting values corresponding to the setting items of other devices having the same meaning as the setting items of the respective devices can be registered.
The information processing device
A creation means for creating a setting value corresponding to a setting item of the other device to be registered in the registration information by using the setting information acquired from the other device, the corresponding information, and the registration information is included. The information processing apparatus according to claim 1 or 2. The creating means uses the corresponding information to identify a setting item included in the registration information having the same meaning as the setting item included in the setting information acquired from the other device, and uses the registration information to identify a setting item. The information processing apparatus according to claim 3, wherein setting values corresponding to the setting items of the other device to be registered in association with the specified setting items are created. The creating means sets the specified setting item according to the degree of matching indicating the degree of matching between the setting value corresponding to the specified setting item and the setting value included in the setting information acquired from the other device. The information processing apparatus according to claim 4, wherein it is determined whether or not the set value of the other device to be associated is a set value included in the setting information acquired from the other device. The set value is a character string and
The creating means compares two characters constituting the set value one by one, calculates the ratio of the number of matching characters to the total number of characters constituting the set value as the matching degree, and the calculated matching degree is a threshold value. The information processing apparatus according to claim 5, wherein in the above case, it is determined that the setting value of the other device associated with the specified setting item is the setting value included in the setting information acquired from the other device. .. In the creation means, when two or more characters constituting the set value match two or more consecutively and then two or more consecutively disagree with each other, the matching character constituting one of the set values and a character that does not match are used. The information processing apparatus according to claim 6, wherein a space for one character is inserted between the two, the set value is reconstructed, and the degree of matching is calculated again. When two or more consecutive characters constituting the set value are inconsistent and then two or more consecutively match, the creating means matches one of the disagreeable characters constituting the set value. The information processing apparatus according to claim 6 or 7, wherein a space for one character is inserted between the characters, the set value is reconstructed, and the degree of matching is calculated again. An information processing system that includes an information processing device that converts setting information and a second device to which the converted setting information is transferred.
The information processing device
An acquisition method for acquiring setting information from the first device,
A processing means for outputting the set value included in the acquired setting information in association with the setting item of the second device by using the correspondence information in which the setting items are associated with each other.
An information processing system including a conversion means for converting the output set value by using the registered information in which the setting item and the set value of each device are registered. It is a method of converting setting information by an information processing device.
The step of acquiring the setting information from the first device,
A step of outputting the setting value included in the acquired setting information in association with the setting item of the second device by using the correspondence information in which the setting items are associated with each other.
A method including a step of converting the output setting value by using the registration information in which the setting item and the setting value of each device are registered. A program for causing a computer to perform each step included in the method according to claim 10.

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