JP2018160247A - Function execution apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology of preventing function setting information from being illegally acquired by a third party.SOLUTION: A CPU 30 of an MFP 10 supplies 802.1x authentication information on a memory 32 to an authentication server 100. The CPU 30 causes the memory 32 to store function setting information used in other MFPs 50 when 802.1x authentication in the authentication server 100 is successful (YES in S12), or controls the memory 32 not to store the function setting information used in other MFPs 50 when 802.1x authentication in the authentication server 100 fails (NO in S12).SELECTED DRAWING: Figure 3

Description

  The technology disclosed in this specification relates to a function execution device that executes at least one function.

  Patent Document 1 discloses a management host computer that manages function setting information of each device in the system. When the image processing apparatus is newly added to the system, the image processing apparatus supplies ID information to the management host computer. The management host computer specifies function setting information necessary for the image processing apparatus based on the ID information of the image processing apparatus, and supplies the function setting information to the image processing apparatus. As a result, the image processing apparatus can execute image processing by using the function setting information acquired from the management host computer.

JP 2000-112863 A

  In the technique of Patent Document 1, for example, when a third party unrelated to the system user adds an image processing apparatus to the system, function setting information of a device in the system can be supplied to the image processing apparatus. That is, the function setting information of the devices in the system can be obtained illegally by a third party.

  The present specification provides a technique that can suppress the occurrence of a situation where function setting information is illegally acquired by a third party.

  The specific function execution device disclosed in the present specification includes a function execution unit, a supply unit, a storage control unit, and a function control unit. The function execution unit executes at least one function including the first function. The supply unit supplies the authentication setting information stored in the first memory to the authentication server. The authentication server performs authentication related to whether or not a specific function execution device is permitted to participate in a specific network by using authentication setting information supplied from the specific function execution device. The storage control unit stores the first function setting information in the second memory when the authentication server succeeds in the authentication, and stores the first function setting information in the second memory when the authentication server fails in the authentication. Do not store in memory. The first function setting information is obtained when the first function execution device among the M function execution devices participating in a specific network (M is an integer of 1 or more) executes the first function. This is function setting information used by the first function execution device. The function control unit causes the function execution unit to execute the first function using the first function setting information stored in the second memory.

According to the above configuration, for example, when a user of a specific network tries to join a specific function execution device to a specific network, authentication in the authentication server is normally successful. In this case, the first function setting information used by the first function execution device participating in the specific network is stored in the second memory. Therefore, the specific function execution device can execute the first function using the first function setting information. On the other hand, even if a third party unrelated to a user of a specific network tries to join a specific function execution device to a specific network, authentication in the authentication server is usually not successful. in this case,
The first function setting information is not stored in the second memory. For this reason, generation | occurrence | production of the situation where 1st function setting information is acquired illegally by the third party can be suppressed.

  Note that a control method, a computer program, and a computer-readable recording medium storing the computer program for realizing the specific function execution device are also novel and useful.

1 shows a configuration of a communication system. An example of number information and a setting information group is shown. 3 shows a flowchart of connection processing executed by a CPU of a multi-function device. 6 shows a flowchart of a setting process executed by the CPU of the multi-function device. The sequence diagram of case A realized by each device is shown. The sequence diagram of case B realized by each device is shown.

(Example)
(Configuration of communication system 2; FIG. 1)
As shown in FIG. 1, the communication system 2 includes a plurality of multi-function devices (hereinafter referred to as “MFP (abbreviation of Multi-Function Peripheral)”) 10, 50, 60, 70, 80, and an authentication server 1.
00. The authentication server 100 is connected to a LAN (abbreviation of Local Area Network) 4. In this embodiment, the LAN 4 is a wired LAN and includes a HUB 90. However, the LAN 4 may be a wireless LAN. Each of the MFPs 50 to 80 participates in the LAN 4. The MFP 10 is a device that can newly participate in the LAN 4. In order for the MFP 10 to participate in the LAN 4, it is necessary that the authentication server 100 succeeds in authentication according to the 802.1x standard.

(Configuration of MFP 10; FIG. 1)
The MFP 10 is a peripheral device (that is, a peripheral device such as a PC (abbreviation of personal computer) not shown) that can execute multiple functions such as a scan function, a print function, and a copy function. The Scan function is a function that scans a document and generates image data. The MFP 10 is, for example, Scan to FTP
It is possible to execute a function of supplying image data obtained by scanning a document to a predetermined external device, such as a function and a Scan to Email function. The Print function is a function for printing an image represented by print data supplied from a PC or the like on a print medium (for example, paper). The Copy function is a function that scans a document, generates image data, and prints an image represented by the image data on a print medium.

  The MFP 10 includes an operation unit 12, a display unit 14, a communication interface 16, a print execution unit 18, a scan execution unit 20, and a control unit 22. Each part 12-22 is connected to the bus line (symbol abbreviation). Hereinafter, the interface is described as “I / F”.

  The operation unit 12 includes a plurality of keys. The user can input various instructions to the MFP 10 by operating the operation unit 12. The display unit 14 is a display for displaying various information. The communication I / F 16 is an interface for executing wired communication, and is connected to a LAN 4 communication cable. The print execution unit 18 is a printing mechanism such as an inkjet method or a laser method. The scan execution unit 20 is a scan mechanism such as a CCD (abbreviation for Charge Coupled Disarmament) or CIS (abbreviation for Contact Image Sensor).

  The control unit 22 includes a CPU 30 and a memory 32. The CPU 30 is a processor that executes various processes according to the program 34 stored in the memory 32. The memory 32 further stores 802.1x authentication information 36, a setting information group 37, and a user table 40.

  The 802.1x authentication information 36 is information for causing the authentication server 100 to execute authentication according to the IEEE 802.1x standard. The IEEE 802.1x standard is a standard in which user authentication is performed when a device is newly connected to a LAN. The 802.1x authentication information 36 includes an authentication ID and a password. In a variation, the 802.1x authentication information 36 may include a digital electronic certificate issued by a certificate authority. The administrator of the communication system 2 (that is, the LAN 4) stores the 802.1x authentication information 36 in advance in the memory of the MFP (for example, the memory 32 of the MFP 10) that should be permitted to participate in the LAN 4.

The setting information group 37 includes a plurality of function setting information corresponding to a plurality of functions that can be executed by the MFP 10. Each function setting information is used by the MFP 10 when a function corresponding to the function setting information is executed by the MFP 10. For example, the function setting information corresponding to the Scan to FTP function includes, for example, the scan resolution, the address of the storage area to which the image data is supplied, the authentication information necessary for accessing the storage area to which the image data is supplied. . The function setting information corresponding to the Print function includes, for example, a paper size, a print resolution, the number of colors (for example, monochrome, color, etc.), and the like. The function setting information for the Copy function includes, for example, scan resolution, paper size, print resolution, number of colors, and the like. These function setting information can be individually set for each user. The user can execute the function by using the function setting information set by the user. At the time of shipment of the MFP 10, a setting information group 37 indicating default function setting information common to users is stored in the memory 32. When the CPU 30 executes a connection process (see FIG. 3) and a setting process (see FIG. 4) described later, the contents of each function setting information included in the setting information group 37 can be added or / and changed.

  The user table 40 includes one or more combination information corresponding to one or more users. Each combination information includes a user ID (for example, “U1”) for identifying a user corresponding to the combination information, a password (for example, “P1”) corresponding to the user, and the user logged into the MFP 10 in the past. And a login flag (for example, “1”) indicating whether or not. The login flag “1” indicates that the user has logged into the MFP 10 in the past (that is, has a login record). The login flag “0” indicates that the user has never logged in to the MFP 10 (that is, there is no login record). The administrator sets the user ID and password of the user who can use the MFP 10 in the user table 40 in advance. The login flag at the time of setting by the administrator is “0” for all users.

  The memory 32 includes a MAC address storage area (not shown) for storing the MAC address of the MFP 10. The MAC address of the MFP 10 is “00: 11: 22: 33: 44: 04”. Of the 48-bit value of the entire MAC address, a portion from the beginning to 24 bits (that is, a “00:11:22” portion, hereinafter referred to as a “leading portion”) identifies the vendor that provides the MFP 10. Indicates the value of. That is, each MFP having the same MAC address head portion is provided (ie, manufactured) by the same vendor.

  The memory 32 further includes a number information storage area (not shown). The number information storage area stores number information indicating the number of times the MFP 10 has executed each function for each user ID.

(Configuration of MFP 50, 60, 70, 80; FIG. 1)
Each of the MFPs 50 to 80 has the same configuration as that of the MFP 10. The head part of the MAC address of each MFP 50, 60, 70 (ie, “00:11:22” part) is the MA of the MFP 10.
Common to the top part of the C address. That is, the MFPs 10, 50, 60, and 70 are provided by the same vendor. The head part of the MAC address of the MFP 80 (that is, the “88:99:00” part) is different from the head part of the MAC address of the MFP 10 or the like. That is, the MFP 80 is provided by a vendor different from the vendor such as the MFP 10. The MFPs 50, 60, and 70 store the number-of-times information 52, 62, and 72, respectively. The MFPs 50, 60, and 70 store setting information groups 54, 64, and 74, respectively.

  Each of the MFPs 50, 60, and 70 stores a user table (not shown). Similar to the user table of the MFP 10, the user table of each MFP includes one or more combination information corresponding to one or more users. Each combination information includes a user ID (for example, “U1”) for identifying a user corresponding to the combination information, a password (for example, “P1”) corresponding to the user, and the user logged into the MFP 10 in the past. And a login flag (for example, “1”) indicating whether or not.

(The contents of the number information 52, 62, 74 and the setting information groups 54, 64, 74; FIG. 2)
As shown in FIG. 2, the frequency information 52 of the MFP 50 includes the number of executions of each function (Scan to FTP function, Print function, Copy function) for each user ID. For example, in the MFP 50, the user with the user ID “U1” executes the Scan to FTP function 30 times, and the user ID “U2”.
The user has executed the Scan to FTP function 50 times, and the user with the user ID “U3” has executed the Scan to FTP function 100 times. Each function described in this embodiment is an example, and includes functions other than the Scan to FTP function, the Print function, and the Copy function, for example, the Scan to Email function.

The setting information group 54 includes function setting information corresponding to each function. Each function setting information includes information for each user ID. For example, the function setting information corresponding to the Scan to FTP function is the user I
Function setting information “xxxxxx” used by the MFP 50 when the user of D “U1” causes the MFP 50 to execute the Scan to FTP function is included.

  As described above, the setting information group 54 and the frequency information 52 of the MFP 50 include information corresponding to the user IDs “U1”, “U2”, and “U3”. Accordingly, the users with the user IDs “U1”, “U2”, and “U3” log in to the MFP 50 in the past and use the MFP 50. In other words, the MFP 50 has a login record of each user with the user IDs “U1”, “U2”, and “U3”. Therefore, in the user table (not shown) of the MFP 50, the login flags corresponding to the users with the user IDs “U1”, “U2”, and “U3” are all “1”.

Similar to the frequency information 52 of the MFP 50, the frequency information 62 of the MFP 60 includes the number of times each function is executed for each user ID. However, the number information 62 does not include information corresponding to the user ID “U2”. The setting information group 64 of the MFP 60 is different from the setting information group 54 including the function setting information group for each function in that it includes information for each user ID (that is, “U1”, “U3”). For example, the setting information group 64 includes a function setting information group used when the user with the user ID “U1” executes each function of the MFP 60. The function setting information group corresponding to the user ID “U1” includes the function setting information “aaaaaa” when the user with the user ID “U1” executes the Scan to FTP function on the MFP 60, and the user performs the Print function on the MFP 60. This includes function setting information “bbbbbb” when executing, and function setting information “cccccc” when the same user executes the Copy function on the MFP 60.

As described above, the setting information group 64 and the number-of-times information 62 include information corresponding to each user with the user IDs “U1” and “U3”. However, the setting information group 64 and the number information 62 do not include information corresponding to the user with the user ID “U2”. That is, the MFP 60 uses the user ID “U1”.
, “U3” has a login record for each user, but the user ID “U2” has no login record. Therefore, in the user table (not shown) of the MFP 60, the login flag corresponding to each user with the user IDs “U1” and “U3” is “1”, but the login flag corresponding to the user with the user ID “U2” is present. “0”.

  Similar to the frequency information 52 of the MFP 50, the frequency information 72 of the MFP 70 includes the number of times each function is executed for each user ID. However, the frequency information 62 includes only information corresponding to the user ID “U1” and does not include information corresponding to the user IDs “U2” and “U3”. Further, the setting information group 74 of the MFP 70 includes function setting information corresponding to each function, like the setting information group 54 of the MFP 50. Each function setting information includes information for each user ID. However, the setting information group 74 includes only information corresponding to the user ID “U1” and does not include information corresponding to the user IDs “U2” and “U3”.

  The setting information group 74 and the number-of-times information 72 include only information corresponding to the user with the user ID “U1”, and do not include information corresponding to the users with the user IDs “U2” and “U3”. That is, the MFP 70 has a login record of the user with the user ID “U1”, but does not have a login record of each user with the user IDs “U2” and “U3”. That is, in the user table (not shown) of the MFP 70, the login flag corresponding to the user with the user ID “U1” is “1”, but the login flag corresponding to each user with the user IDs “U2” and “U3”. “0”.

(Configuration of authentication server 100; FIG. 1)
The authentication server 100 in FIG. 1 uses the 802.1x authentication information (for example, symbol 36 in FIG. 1) to authenticate in accordance with the IEEE 802.1x standard (hereinafter, sometimes referred to as “802.1x authentication”). It is a server that executes The authentication server 100 is connected to the LAN 4 by the administrator of the communication system 2. For example, when the MFP 10 is to newly participate in the LAN 4, the administrator stores the 802.1x authentication information 36 in the memory 32 of the MFP 10 and stores the 802.1x authentication information 36 in the authentication server 100.

(Configuration of HUB90; Fig. 1)
The HUB 90 is a LAN switch corresponding to the IEEE 802.1x standard. The HUB 90 mediates a communication packet for 802.1x authentication communicated between the MFP 10 or the like that is a client and the authentication server 100. Whether the HUB 90 allows a client (that is, the MFP 10 or the like) connected to the LAN 4 to execute communication via the LAN 4 depending on whether or not the 802.1x authentication in the authentication server 100 is successful. Control whether or not. More specifically, the HUB 90 allows a client that has succeeded in 802.1x authentication to perform communication with another client via the LAN 4. On the other hand, the HUB 90 refuses that a client that has failed 802.1x authentication communicates with another client via the LAN 4.

(Connection process executed by CPU 30 of MFP 10; FIG. 3)
Next, a connection process executed by the CPU 30 of the MFP 10 will be described with reference to FIG. When the MFP 10 is turned on while the communication cable connected to the LAN 4 is connected to the communication I / F 16 of the MFP 10, the CPU 30 starts the connection process of FIG.

  In S <b> 10, the CPU 30 supplies the 802.1x authentication information 36 stored in the memory 32 to the HUB 90. In subsequent S <b> 12, the CPU 32 determines whether or not 802.1x authentication in the authentication server 100 is successful.

When the HUB 90 acquires the 802.1x authentication information 36 supplied in S10 from the MFP 10, the HUB 90 supplies the 802.1x authentication information 36 to the authentication server 100. When the authentication server 100 acquires the 802.1x authentication information 36 from the HUB 90, the authentication server 100 executes the 802.1x authentication using the acquired 802.1x authentication information 36. Specifically, the authentication server 100 determines whether or not the 802.1x authentication information 36 is stored in the memory of the authentication server 100. When the 802.1x authentication information 36 is stored in the memory of the authentication server 100, the authentication server 100 determines that the 802.1x authentication is successful and supplies the success information to the HUB 90. On the other hand, when the 802.1x authentication information 36 is not stored in the memory of the authentication server 100, the authentication server 100 determines that the 802.1x authentication has failed and supplies the failure information to the HUB 90. The HUB 90 supplies success information or failure information acquired from the authentication server 100 to the MFP 10.

  When acquiring success information from the HUB 90, the CPU 30 determines YES in S12. In this case, the CPU 30 ends the connection process of FIG. As a result, the MFP 10 can participate in the LAN 4 and a state in which the MFP 10 can execute communication with other MFPs 50 and the like via the LAN 4 (that is, a communicable state) is established. That is, the HUB 90 allows the MFP 10 to communicate with another MFP 50 or the like via the LAN 4. That is, the HUB 90 executes communication packet relay between the MFP 10 and another MFP 50 or the like. When the connection process ends as a result of the determination of YES in S12 of FIG. 3, the CPU 30 then starts the setting process of FIG.

  On the other hand, when acquiring failure information from the HUB 90, the CPU 30 determines NO in S12. In this case, the MFP 10 cannot participate in the LAN 4 and the above-described communicable state is not established. That is, the HUB 90 rejects the MFP 10 from communicating with another MFP 50 or the like via the LAN 4. That is, the HUB 90 does not perform communication packet relay between the MFP 10 and another MFP 50 or the like. When the connection process ends as a result of the determination of NO in S12 of FIG. 3, the CPU 30 does not start the setting process of FIG. In this case, for example, the CPU 30 may cause the display unit 14 to display information indicating that the MFP 10 cannot participate in the LAN 4 due to the failure of the 802.1x authentication.

(Setting process executed by CPU 30 of MFP 10; FIG. 4)
Next, a setting process executed by the CPU 30 will be described with reference to FIG. In S30, the CPU 30 monitors the acquisition of user information (that is, user ID and password). The user of the MFP 10 operates the operation unit 12 of the MFP 10 to input an execution instruction for a desired function (for example, a Scan to FTP function) and input user information. However, if the user wishes to execute the Print function of the MFP 10, the user
Print data and a print function execution instruction are supplied in advance from the PC to the MFP 10, and then the user goes to the MFP 10 and operates the operation unit 12 to input user information. Note that the user may input only user information without inputting an instruction to execute a desired function. When the user information is input, the CPU 30 determines YES in S30, and proceeds to S32.

  In S <b> 32, the CPU 30 determines whether the user information (that is, user ID and password) acquired in S <b> 30 exists in the user table 40 of the memory 32. If the combination information including the user information exists in the user table 40, the CPU 30 determines YES in S32 and proceeds to S34. If the combination information including the user information does not exist in the user table 40, the CPU 30 determines NO in S32 and ends the setting process of FIG.

In S <b> 34, the CPU 30 determines whether or not it is the first login by the user of the user ID (hereinafter, referred to as “specific user ID”) included in the user information acquired in S <b> 30. Specifically, in S34, the CPU 30 refers to the user table 40, and determines whether or not the login flag corresponding to the specific user ID is “0”. When the login flag is “0” (that is, when there is no login record), the CPU 30 determines YES in S34 and proceeds to S36. At this time, the CPU 30 changes the login flag corresponding to the specific user ID from “0” to “1”. On the other hand, when the login flag corresponding to the specific user ID is “1” at the time of S34 (that is, when the user has already logged in), the CPU 30 determines NO in S34 and performs the setting process of FIG. finish.

  In S36, the CPU 30 broadcasts a predetermined request signal to the LAN 4. The request signal is a signal for requesting a specific MFP among the other MFPs 50 to 80 in the LAN 4 to supply a response signal. The specific MFP is an MFP whose vendor is the same as that of the MFP 10 and has a login record by a user having a specific user ID. The request signal includes a specific user ID and the MAC address of the MFP 10.

  When each of the MFPs in the LAN 4 (that is, the MFPs 50 to 80) acquires the request signal, the MFP 4 determines whether the vendor of the MFP and the vendor of the MFP 10 are common. Specifically, each MFP determines whether or not the leading portion of the MAC address of the MFP and the leading portion (“00:11:22”) of the MAC address of the MFP 10 included in the request signal match. To do. If the two match, the MFP determines that the MFP vendor and the MFP 10 vendor are common. If the two do not match, the MFP determines that the vendor of the MFP and the vendor of the MFP 10 are not common, and does not supply a response signal to the MFP 10.

  If each MFP in the LAN 4 determines that the vendor of the MFP and the vendor of the MFP 10 are common, the MFP 4 further determines whether or not the user has a login record of a specific user ID included in the request signal. Specifically, each MFP includes a user ID that matches a specific user ID in its own user table, and whether or not the login flag corresponding to the user ID is “1”. Judging. When the user ID matching the specific user ID is included in the own user table and the login flag corresponding to the specific user ID is “1” (that is, the user of the specific user ID If the user has a login record, the MFP (that is, the specific MFP) generates a response signal including frequency information indicating the frequency of use of each function corresponding to the specific user, and supplies the response signal to the MFP 10. On the other hand, when the user ID that matches the specific user ID is not included in the own user table, or the user ID that matches the specific user ID exists in the own user table, the user ID When the corresponding login flag is “0” (that is, when the user with the specific user ID does not have a login record), the MFP does not supply a response signal to the MFP 10.

  In S38, the CPU 30 determines whether a response signal has been acquired from at least one specific MFP. When one or more response signals are acquired from one or more specific MFPs, the CPU 30 determines YES in S38 and proceeds to S40. On the other hand, if the response signal is not acquired, the CPU 30 determines NO in S38 and ends the setting process of FIG.

In S <b> 40, the CPU 30 specifies one of a plurality of functions that can be executed by the MFP 10 (for example, a Scan to FTP function). Hereinafter, the function specified in S40 may be referred to as a “specific function”.

  In subsequent S42, the CPU 30 identifies the MFP having the most frequently executed specific function. Specifically, in S42, the CPU 30 refers to the frequency information included in the one or more response signals, and refers to the MFP that is the source of the response signal including the maximum number of execution times of the specific function (hereinafter “maximum MFP”). ”).

In subsequent S44, the CPU 30 selects a specific user I from the most frequent MFP specified in S42.
The function setting information of a specific function corresponding to D is acquired. Specifically, in S44, the CPU 30 supplies a request signal for requesting supply of function setting information of a specific function corresponding to a specific user ID to the most frequent MFP, and acquires the function setting information from the most frequent MFP. .

  In subsequent S46, the CPU 30 determines whether or not the number of executions of the specific function included in the response signal acquired in S38 from the most frequent MFP is equal to or greater than a predetermined threshold. In the present embodiment, the threshold is 10 times, but may be a different value in the modification. When the execution count of the specific function is equal to or greater than the threshold, the CPU 30 determines YES in S46 and proceeds to S54. On the other hand, if the number of executions of the specific function (S42) is smaller than the threshold, the CPU 30 determines NO in S46 and proceeds to S48.

  In S48, the CPU 30 displays the content of the function setting information acquired in S44 on the display unit 14. At the same time, the CPU 30 displays a message for requesting an input of an instruction as to whether or not the function setting information being displayed is stored in the memory 32 on the display unit 14. The user looks at the contents of the function setting information displayed on the display unit 14 and operates an instruction whether or not to store the function setting information being displayed (that is, the function setting information acquired in S44) in the memory 32. It can be input to the unit 12.

  In S50, the CPU 30 determines whether or not an instruction for storing the function setting information acquired in S44 in the memory 32 (hereinafter, also referred to as “storage instruction”) is input by the user. When the storage instruction is input, the CPU 30 determines YES in S50, and proceeds to S54. On the other hand, if the storage instruction has not been input, the CPU 30 determines NO in S50 and proceeds to S52.

  In S52, the CPU 30 determines whether or not all of the one or more specific MFPs that are the sources of the one or more response signals acquired in S38 have been specified in S42. If all the specific MFPs are specified at the time of S52, the CPU 30 determines YES in S52, and does not store the function setting information acquired in S44 in the memory 32 (that is, skips S54). Go to S56. On the other hand, if all the specific MFPs have not yet been specified, the CPU 30 determines NO in S52 and returns to S42. In S <b> 42, the CPU 30 newly specifies a specific MFP having the next highest number of executions of a specific function among one or more specific MFPs that have not yet been specified, and repeats the processing after S <b> 44 again. Run.

  On the other hand, in S54, the CPU 30 replaces the function setting information of the specific function currently included in the setting information group 37 in the memory 32 (that is, function setting information indicating the default setting), and acquires the function setting information acquired in S44. Is newly memorized.

  Next, in S56, the CPU 30 determines whether all of a plurality of functions that can be executed by the MFP 10 have been specified in S40. If all the functions are specified at the time of S56, the CPU 30 determines YES in S56 and ends the setting process of FIG. On the other hand, if all the functions have not yet been specified, the CPU 30 determines NO in S56 and returns to S40. In S <b> 40, the CPU 30 newly specifies one function that has not yet been specified as a specific function, and executes the processes subsequent to S <b> 42 again.

When an instruction to execute a desired function is input together with the user information in S30, the CPU 30 completes the setting process in FIG. 4 and the desired setting included in the function setting information corresponding to the user in the memory 32. The function setting information corresponding to the function is used to execute a desired function. For example, when the desired function is the Scan to FTP function, the CPU 30 causes the scan execution unit 20 to execute a scan according to the scan resolution included in the function setting information, and sets the generated image data to an address included in the function setting information. Supply. Also, for example, the desired function
In the case of the Print function, the CPU 30 causes the print execution unit 18 to execute printing according to the print resolution included in the function setting information. Further, for example, when the desired function is the Copy function, the CPU 30 causes the scan execution unit 20 to execute a scan according to the scan resolution included in the function setting information, and sets the image represented by the generated image data to the function setting. The printing execution unit 18 is caused to execute printing according to the printing resolution included in the information. When only the user information is input in S30, the CPU 30 causes the user of the specific user ID to input the user information again after completing the setting process in FIG. When inputting, the desired function is executed using the function setting information corresponding to the desired function included in the function setting information corresponding to the user in the memory 32.

(Specific case)
Next, specific cases realized by the flowcharts of FIGS. 2 and 3 will be described with reference to FIGS. 5 and 6.

(Case A; FIG. 5)
Case A shown in FIG. 5 is a specific example of processing executed by each device when a communication cable of LAN 4 is connected to the communication I / F 16 of the MFP 10 newly introduced into the system and the power of the MFP 10 is turned on thereafter. It is. In case A, an example in which a user with a user ID “U1” inputs user information will be described.

  When the power of the MFP 10 is turned on, in T10, the MFP 10 supplies the 802.1x authentication information 36 stored in the memory 32 to the authentication server 100 via the HUB 90 (S10 in FIG. 3). In addition, illustration of HUB90 is abbreviate | omitted in FIG.

  The authentication server 100 performs 802.1x authentication using the 802.1x authentication information 36 acquired from the MFP 10. In this example, the authentication server 100 determines that the 802.1x authentication is successful. In T12, the authentication server 100 supplies success information to the MFP 10 via the HUB 90.

  As a result, a state in which the MFP 10 can communicate with another MFP 50 or the like via the LAN 4 (that is, a communicable state) is established (YES in S12 of FIG. 3).

  In subsequent T14, the user with the user ID “U1” operates the operation unit 12 of the MFP 10 and inputs user information (that is, user ID “U1” and password “P1”) together with an instruction to execute a desired function. .

  In T <b> 16, the MFP 10 determines that the combination information including the input user information is included in the user table 40. At this time, the login flag corresponding to the user ID “U1” is “0”. Therefore, in subsequent T18, the MFP 10 broadcasts a request signal including the user ID “U1”, which is a specific user ID, and the MAC address of the MFP 10 to the LAN 4.

  The MFPs 50, 60, and 70 all have the same vendor as that of the MFP 10 (that is, the head part “00:11:22” of the MAC address is common, see FIG. 1). Further, the MFPs 50, 60, and 70 each have a login record of the user with the user ID “U1” (that is, the login flag corresponding to the user ID “U1” including the user ID “U1” in the user table). Is “1”). Therefore, at T20, upon acquiring the request signal from the MFP 10, the MFPs 50, 60, and 70 supply the MFP 10 with a response signal including the number-of-times information corresponding to the user ID “U1”.

  On the other hand, the vendor of the MFP 80 does not match that of the MFP 10 (that is, the head part of the MAC address is not common, see FIG. 1). Therefore, even if the MFP 80 acquires the request signal, the MFP 80 does not supply a response signal to the MFP 10.

In T22, the MFP 10 specifies the Scan to FTP function (S40 in FIG. 4). MFP5
In 0, 60, and 70, the number of times that the user with the user ID “U1” executed the Scan to FTP function is 30 times (MFP 50), 10 times (MFP 60), and 5 times (MFP 70), respectively (see FIG. 2). ). Therefore, in T24, the MFP 10 identifies the MFP 50 as the most frequent MFP and supplies a request signal to the MFP 50 (S44 in FIG. 4). The request signal includes user ID “U1” and information indicating the Scan to FTP function.

In T26, the MFP 50 acquires the request signal and supplies the MFP 10 with function setting information (that is, “xxxxxx” in FIG. 2) of the Scan to FTP function corresponding to the user ID “U1” (
S44 of FIG. 4).

The MFP 10 acquires function setting information from the MFP 50 (S44 in FIG. 4). Next, in T28, the MFP 10 determines that the number of times that the user with the user ID “U1” has executed the Scan to FTP function in the MFP 50 (that is, 30 times) is greater than the threshold value of 10 times. Therefore, at T30, the MFP 10 automatically stores the function setting information acquired from the MFP 50 in the memory 32.

In T32, the MFP 10 specifies the Print function (S40 in FIG. 4). MFP 50, 6
At 0 and 70, the number of times the user with the user ID “U1” executed the Print function is 0 (MFP 50), 6 (MFP 60), and 5 (MFP 70), respectively. Therefore, in T34, the MFP 10 specifies the MFP 60 as the most frequent MFP and supplies a request signal to the MFP 60 (S44 in FIG. 4). The request signal includes user ID “U1” and information indicating the Print function.

In T36, the MFP 60 acquires the request signal, and supplies the MFP 10 with function setting information (that is, “bbbbbb” in FIG. 2) corresponding to the user ID “U1” (S44 in FIG. 4).

The MFP 10 acquires function setting information from the MFP 60 (S44 in FIG. 4). Next, in T38, the MFP 10 determines that the number of times that the user with the user ID “U1” executed the Print function in the MFP 60 (that is, 6 times) is smaller than the threshold value of 10 times. Therefore, at T40, the MFP 10 displays the function setting information acquired from the MFP 60 on the display unit 14.

  The user inputs an instruction to the MFP 10 not to store the function setting information acquired from the MFP 60 in the memory 32 (NO in S50 of FIG. 4).

Therefore, at T <b> 42, the MFP 10 does not store the function setting information acquired from the MFP 60 in the memory 32. In subsequent T44, the MFP 10 newly specifies the MFP 70 having the second largest number of executions of the Print function as the most frequent MFP, and supplies a request signal to the MFP 70 (S44 in FIG. 4).

  In T46, the MFP 70 acquires the request signal and supplies function setting information of the Print function corresponding to the user ID “U1” to the MFP 10 (S44 in FIG. 4).

The MFP 10 acquires function setting information from the MFP 70 (S44 in FIG. 4). Then T
In 48, the MFP 10 determines that the number of times that the user with the user ID “U1” has executed the Print function in the MFP 60 (that is, 5 times) is smaller than the threshold value of 10 times. Therefore, at T50, the MFP 10 displays the function setting information acquired from the MFP 70 on the display unit 14.

  The user inputs an instruction to store the function setting information acquired from the MFP 70 in the memory 32 to the MFP 10 (YES in S50 of FIG. 4).

  Therefore, in T52, the MFP 10 stores the function setting information acquired from the MFP 70 in the memory 32 (S54 in FIG. 4).

  In T54, the MFP 10 specifies the Copy function (S40 in FIG. 4). In MFPs 50, 60, and 70, the number of times that the user with the user ID “U1” has executed the Copy function is 20 times (MFP 50), 10 times (MFP 60), and 10 times (MFP 70), respectively. Therefore, in T56, the MFP 10 specifies the MFP 50 as the most frequent MFP and supplies a request signal to the MFP 50 (S44 in FIG. 4). The request signal includes user ID “U1” and information indicating the Copy function.

  In T58, the MFP 50 acquires the request signal and supplies function setting information of the Copy function corresponding to the user ID “U1” to the MFP 10 (S44 in FIG. 4).

  The MFP 10 acquires function setting information from the MFP 50. Next, in T60, the MFP 10 determines that the number of times that the user with the user ID “U1” has executed the Copy function in the MFP 50 (that is, 20 times) is larger than the threshold value of 10 times. Therefore, at T62, the MFP 10 automatically stores the function setting information acquired from the MFP 50 in the memory 32.

  Thereafter, in T64, the MFP 10 executes the function desired by the user in accordance with the function execution instruction input in T14. At that time, the MFP 10 executes a desired function using the function setting information corresponding to the desired function included in the function setting information corresponding to the user with the user ID “U1” in the memory 32.

(Case B; FIG. 6)
Case B shown in FIG. 6 is an example in which after completion of case A, the user with the user ID “U2” continues to input user information to the MFP 10.

  At T80, the user with the user ID “U2” operates the operation unit 12 of the MFP 10 and inputs user information (that is, user ID “U2” and password “P2”) together with an instruction to execute a desired function.

  In T <b> 82, the MFP 10 determines that the combination information including the input user information is included in the user table 40. At this time, the login flag corresponding to the user ID “U2” is “0”. Therefore, in subsequent T84, the MFP 10 broadcasts a request signal including the user ID “U2” that is a specific user ID and the MAC address of the MFP 10 to the LAN 4.

The MFPs 50, 60, and 70 all have the same vendor as that of the MFP 10 (that is, the head part “00:11:22” of the MAC address is common, see FIG. 1). However, only the MFP 50 has a login record of the user with the user ID “U2” (that is, the user table includes the user ID “U2” and the login flag corresponding to the user ID “U2” is “1”).
"). Therefore, in T86, when the MFP 50 acquires the request signal from the MFP 10, the MFP 50 supplies the MFP 10 with a response signal including the number-of-times information corresponding to the user ID “U2”.

  On the other hand, the MFPs 60 and 70 have the same vendor as the MFP 10 but do not have a login record of the user with the user ID “U2” (that is, the user ID “U2” is included in the user table, but the user ID “U2”). The login flag corresponding to is “0”). Further, in the MFP 80, the vendor does not match the MFP 10 (that is, the head part of the MAC address is not common, see FIG. 1). Therefore, even if the MFPs 60, 70, and 80 obtain the request signal, they do not supply a response signal to the MFP 10.

In T88, the MFP 10 specifies the Scan to FTP function (S40 in FIG. 4). MFP1
0 acquires only the response signal from the MFP 50. Therefore, in T90, the MFP 10 specifies the MFP 50 as the most frequent MFP and supplies a request signal to the MFP 50 (S44 in FIG. 4).

In T92, the MFP 50 acquires the request signal and supplies the MFP 10 with the function setting information of the Scan to FTP function corresponding to the user ID “U2” (that is, “yyyyyy” in FIG. 2) (
S44 of FIG. 4).

The MFP 10 acquires function setting information from the MFP 50 (S44 in FIG. 4). Next, in T94, the MFP 10 determines that the number of times that the user with the user ID “U2” executed the Scan to FTP function in the MFP 50 (that is, 50 times) is larger than the threshold value of 10 times. Therefore, in T96, the MFP 10 automatically stores the function setting information acquired from the MFP 50 in the memory 32.

In T98, the MFP 10 specifies the Print function (S40 in FIG. 4). Again, T
In 100, the MFP 10 identifies the MFP 50 as the most frequent MFP and supplies a request signal to the MFP 50 (S44 in FIG. 4).

  In T102, the MFP 50 acquires the request signal and supplies function setting information of the Print function corresponding to the user ID “U2” to the MFP 10 (S44 in FIG. 4).

The MFP 10 acquires function setting information from the MFP 50 (S44 in FIG. 4). Next, in T104, the MFP 10 determines that the number of times that the user with the user ID “U2” executed the Print function in the MFP 50 (that is, 5 times) is smaller than the threshold value of 10 times. Therefore, in T106, the MFP 10 displays the function setting information acquired from the MFP 50 on the display unit 14.

  The user inputs an instruction to store the function setting information acquired from the MFP 50 in the memory 32 to the MFP 10 (YES in S50 of FIG. 4).

  Therefore, in T108, the MFP 10 stores the function setting information acquired from the MFP 50 in the memory 32 (S54 in FIG. 4).

  In T110, the MFP 10 specifies the Copy function (S40 in FIG. 4). Similarly, in T112, the MFP 10 specifies the MFP 50 as the most frequent MFP, and supplies a request signal to the MFP 50 (S44 in FIG. 4).

  In T114, the MFP 50 acquires the request signal and supplies function setting information of the Copy function corresponding to the user ID “U2” to the MFP 10 (S44 in FIG. 4).

  The MFP 10 acquires function setting information from the MFP 50. Next, in T116, the MFP 10 determines that the number of times that the user with the user ID “U1” executed the Copy function in the MFP 50 (that is, 5 times) is smaller than the threshold value of 10 times. Therefore, at T118, the MFP 10 displays the function setting information acquired from the MFP 50 on the display unit 14.

  The user inputs an instruction to the MFP 10 not to store the function setting information acquired from the MFP 50 in the memory 32 (NO in S50 of FIG. 4).

  Therefore, at T120, the MFP 10 does not store the function setting information acquired from the MFP 50 in the memory 32 (YES in S52 of FIG. 4, YES in S56).

  Thereafter, in T122, the MFP 10 executes the function desired by the user in accordance with the function execution instruction input in T14. At this time, the MFP 10 executes a desired function using the function setting information corresponding to the desired function included in the function setting information corresponding to the user with the user ID “U2” in the memory 32.

(Effect of Example)
As described above, in this embodiment, when the 802.1x authentication is successful in the authentication server 100 (YES in S12 of FIG. 3), the MFP 10 stores the function setting information used in other MFPs 50 and the like in the memory 32. (S54 in FIG. 4), and when the 802.1x authentication in the authentication server 100 fails (NO in S12 in FIG. 3), the function setting information used in other MFPs 50 or the like is not stored in the memory 32. . For example, when a user of the LAN 4 tries to join the MFP 10 to the LAN 4, the 802.1x authentication in the authentication server 100 is normally successful. In this case, function setting information used by another MFP participating in the LAN 4 (for example, the MFP 50 or the like) is stored in the memory 32. For this reason, the MFP 10 is used by another MFP participating in the LAN 4. On the other hand, even if a third party unrelated to the user of LAN 4 attempts to join an unrelated MFP to LAN 4, authentication is usually performed. The 802.1x authentication does not succeed in the server 100. In this case, the first function setting information is not stored in the second memory, and is used by another MFP participating in the LAN 4 by a third party. In this embodiment, the administrator can newly join the MFP 10 to the LAN 4 because the function setting information is illegally acquired. Initial settings (for example, settings relating to the network, settings relating to 802.1x authentication, etc.) necessary for the user are performed in advance, while the function setting information set individually for each user has set values (that is, The contents of the function setting information cannot be set together at the time of initial setting, so such function setting information needs to be set by each user after the MFP 10 participates in the LAN 4. According to this embodiment, since the information used by another MFP can be automatically stored in the memory 32 in the MFP 10, the troublesome setting operation by the user can be eliminated.

  In the examples of FIGS. 5 and 6, the MFP 10 acquires user information input when an instruction to execute a function desired by the user is given (T14 in FIG. 5 and T80 in FIG. 6). That is, the function setting information can be automatically stored in the memory 32 without causing the user to perform an operation for storing the function setting information in the memory 32. That is, the MFP 10 can store the function setting information in the memory 32 at an appropriate timing.

Further, as illustrated in the example of FIG. 5, the MFP 10 acquires function setting information of each function from the MFPs 50, 60, and 70 that have the same vendor as the MFP 10 and have a login record by the user with the user ID “U1”. can do. Further, as shown in the example of FIG.
Can acquire the function setting information of each function from the MFP 50 that is shared by the MFP 10 and the vendor and has a login record by the user with the user ID “U2”. Since the vendor of the MFP 10 and the vendors of the MFPs 50, 60, and 70 are common, there is a high possibility that the function setting information acquired from the MFPs 50, 60, and 70 can be appropriately used when the MFP 10 executes the function. Further, the function setting information acquired from the MFPs 50, 60, and 70 having the login record of the user with the user ID “U1” is highly likely to indicate the setting desired by the user with the user ID “U1”. Similarly, the function setting information acquired from the MFP 50 having the login history of the user with the user ID “U2” is highly likely to indicate the setting desired by the user with the user ID “U2”. That is, according to the MFP 10 of this embodiment, appropriate function setting information can be stored in the memory 32 for each user. Since the function setting information corresponding to the user who has not logged in to the MFP 10 is not stored in the memory 32, the memory load on the MFP 10 due to the function setting information of the user who has not logged in to the MFP 10 can be reduced, and unnecessary function setting information is stored. Therefore, it is possible to reduce the operation load for the user to select specific function setting information from a plurality of function setting information.

Further, as shown in the example of FIG. 5, the MFP 10 uses the MFP 5 for the Scan to FTP function.
The function setting information acquired from 0 is stored in the memory 32.
The function setting information acquired from 70 is stored in the memory 32, and the function setting information acquired from the MFP 50 is stored in the memory 32 for the Copy function. That is, according to the MFP 10 of this embodiment, function setting information appropriate for each function can be stored in the memory 32.

  Further, as illustrated in the example of FIG. 5, the MFP 10 identifies the most frequent MFP from the MFPs 50, 60, and 70 based on the number of executions for each function, and acquires function setting information from the most frequent MFP. That is, according to the MFP 10 of the present embodiment, appropriate function setting information can be stored in the memory 32 in accordance with the results of execution of each function in the MFPs 50, 60, and 70.

  Also, as shown in the examples of FIGS. 5 and 6, when the MFP 10 determines that the number of times that the most frequent MFP has executed the function is smaller than the threshold value, the display unit 14 displays the content of the function setting information acquired from the most frequent MFP. The function setting information acquired from the most frequent MFP is stored in the memory 32 when a storage instruction is input from the user. In some cases, it is preferable for the user not to store the function setting information acquired from the most frequent MFP in the memory 32 when the number of times that the most frequent MFP has executed the function is smaller than a threshold value. Therefore, according to the MFP 10 of the present embodiment, appropriate function setting information can be stored in the memory 32.

(Correspondence)
The MFP 10 is an example of a “specific function execution device”. The print execution unit 18 and the scan execution unit 20 are examples of a “function execution unit”. The scan execution unit 20 is an example of a “reading unit”. The Scan to FTP function is an example of an “image processing function”. The memory 32 is an example of a “first memory” and a “second memory”. The LAN 4 is an example of a “specific network”. The 802.1x authentication and the 802.1x authentication information 36 are examples of “authentication” and “authentication setting information”, respectively. The user ID “U1” and the user ID “U2” are examples of “first user information” and “second user information”, respectively. Function setting information (“xxxxxx” in FIG. 2) of the Scan to FTP function acquired from the MFP 50 in the example of FIG. 5, the MFP in the example of FIG.
The function setting information (“yyyyyy” in FIG. 2) of the Scan to FTP function acquired from 50 and the function setting information (“dddddd” in FIG. 2) of the Print function acquired from the MFP 70 in the example of FIG. It is an example of “first function setting information”, “second function setting information”, and “third function setting information”. The Scan to FTP function and the Print function are examples of “first function” and “second function”, respectively. The MFPs 50, 60, 70, and 80 are examples of “M function execution devices”. In addition, the MFPs 50, 60, and 70 in the example of FIG. 5 and the MFP 50 in the example of FIG. 6 are examples of “N function execution devices”. The number of times information included in the response signal is "result information"
It is an example.

  The process of S10 in FIG. 3 is an example of a process executed by the “supply unit”. The process of S12 in FIG. 3 and the process of S54 in FIG. 4 are examples of processes executed by the “storage control unit”. The process in the case of YES in S30 in FIG. 4 and the process in S44 in FIG. 4 are examples of processes executed by the “user information acquisition unit” and the “function setting information acquisition unit”, respectively. The process in the case of YES in S38 in FIG. 4 and the process in S42 in FIG. 4 are examples of processes executed by the “result information acquisition unit” and the “selection unit”, respectively. The processes at T64 in FIG. 5 and T122 in FIG. 6 are examples of processes executed by the “function control unit”.

  Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The modifications of the above embodiment are listed below.

(Modification 1) The user table 40 includes a user ID (for example, U1), a password (for example, P1) corresponding to the user ID, and a login flag (for example, 1) corresponding to the user ID, Information indicating whether the user can use the Scan to FTP function (OK or NG), and information indicating whether the user can use the Print function (O
K or NG) and information indicating whether or not the user can use the Copy function (OK or NG) may be included. In this modification, the CPU 30 of the MFP 10 refers to the user table 40 when specifying one of a plurality of functions that can be executed by the MFP 10 in S40 of FIG. It is also possible to specify the function associated with the information indicating that the user (that is, OK) and not specify the function associated with the information indicating that the user is not available (that is, NG). The CPU 30 may store function setting information acquired from other MFPs in the memory 32 only for functions available to the user.

(Modification 2) In the above-described embodiment, the MFPs 10, 50 to 80 and the authentication server 100 are connected via the HUB 90 and the LAN 4 so that wired communication is possible. Instead of this, the MFPs 10, 50 to 80, and the authentication server 100 may be capable of wireless communication with each other via an AP (abbreviation of Access Point). In this modification, the AP corresponds to the IEEE 802.1x standard. That is, in this modification, the AP may mediate a communication packet for 802.1x authentication supplied and acquired between the MFP 10 or the like as the client and the authentication server 100. Whether the AP permits the MFP 10 as a client to execute wireless communication with another MFP 50 or the like via the AP, depending on whether or not the 802.1x authentication in the authentication server 100 is successful. May be controlled. The wireless communication network in this modification is an example of a “specific network”.

(Modification 3) In the above embodiment, in S46 of FIG. 4, the CPU 30 of the MFP 10 determines whether or not the maximum number of executions (S42) of a specific function by the most frequent MFP is equal to or greater than a predetermined threshold value. Yes. Instead, the CPU 30 of the MFP 10 determines the function setting information (FIG. 4) from the most frequently used MFP without determining whether the most frequently executed specific function by the most often MFP is equal to or greater than a predetermined threshold. (See S44) may be stored in the memory 32. In another example, the CPU 30 displays the content of the function setting information acquired from the most frequently used MFP without determining whether the most frequently executed specific function by the most frequently used MFP is equal to or greater than a predetermined threshold. 14 may request the user to input an instruction as to whether or not to store the function setting information in the memory 32. In this case, the CPU 30 may store the function setting information acquired from the most frequent MFP in the memory 32 when a storage instruction is input.

(Modification 4) In the above embodiment, each of the MFPs 10 and 50 to 70 has the setting information group 37.
, 54, 64, 74 are stored in the memory of the own device. Instead, the MFPs 10 and 50 to 70 may store the setting information groups 37, 54, 64, and 74 in an external server. In this modification, the CPU 30 of the MFP 10 replaces the function setting information for the MFP 10 in the external server (that is, the setting information group 37) with the other storage area in place of acquiring the function setting information from another MFP 50 or the like. The function setting information for the MFP 50 or the like may be copied. The external server in this modification is an example of a “second memory”.

(Modification 5) The memory 32 of the MFP 10 stores 802.1x authentication information 36 used for 802.1x authentication. Instead, the 802.1x authentication information 36 may be stored in the external server. The CPU 30 may supply the 802.1x authentication information 36 read from the external server to the authentication server 100 via the HUB 90 in S10 of FIG. In this modification, the external server is an example of a “first memory”.

(Modification 6) In the above embodiment, the CPU 30 specifies the most frequent MFP based on the number of times information included in one or more response signals acquired from one or more specific MFPs, and functions from the most frequent MFP. Setting information is acquired (YES in S38 of FIG. 4, S40 to S44). Not limited to this, one or more response signals acquired from one or more specific MFPs may include the latest execution time information indicating the time at which each function was last executed. In that case, the CPU 30 performs the last execution of the specific function (hereinafter referred to as “latest MFP” based on the latest execution time information included in the one or more response signals acquired from the one or more specific MFPs. May be specified). The CPU 30 may acquire function setting information from the identified latest MFP. In this modification, the latest execution time information is an example of “result information”.

(Modification 7) In the above embodiment, the CPU 30 obtains a response signal only from a specific MFP (YES in S38 of FIG. 4). However, the present invention is not limited to this, and the CPU 30 may acquire response signals from all the MFPs 50 to 80 in the LAN 4. In this modification, after acquiring response signals from all the MFPs 50 to 80, the CPU 30 may specify a specific MFP from the MFPs 50 to 80 based on information included in the response signals. The CPU 30 may specify the most frequent MFP from among the specific MFPs, and acquire function execution information from the most frequent MFP. Generally speaking, the selection unit may select the first function execution device among the N function execution devices provided by the first vendor.

(Modification 8) In the above embodiment, in S36 of FIG. 4, the CPU 30 broadcasts a request signal including a specific user ID and the MAC address of the MFP 10 to the LAN 4. Instead, the CPU 30 may broadcast a request signal including only a specific user ID to the LAN 4. In this case, the CPU 30 may acquire a response signal from an MFP having a login record by a user with a specific user ID regardless of the vendor. In another example, the CPU 30 may broadcast a request signal including only the MAC address of the MFP 10 to the LAN 4. In this case, the CPU 30 may acquire a response signal from the MFP that is common to the MFP 10 and the vendor regardless of whether or not the user with the specific user ID has logged in.

(Modification 9) In the above embodiment, the authentication server 100 executes 802.1x authentication according to the IEEE802.1x standard. The memory 32 of the MFP 10 stores 802.1x authentication information 36 used for 802.1x authentication. Instead, the authentication server 100 may perform authentication according to a standard other than the IEEE 802.1x standard. The memory 32 of the MFP 10 may store authentication information used for the authentication. Generally speaking, the supply unit may supply authentication setting information stored in the first memory to the authentication server. The authentication server may perform authentication related to whether or not a specific function execution device is allowed to participate in a specific network by using authentication setting information supplied from the specific function execution device.

(Modification 10) The operation unit 12 and the display unit 14 of the MFP 10 may be integrally configured as a touch panel. That is, the operation unit 12 and the display unit 14 of the MFP 10 may be configured by a single piece of hardware.

(Modification 11) The user table may not be stored in the memory of each MFP. The user table may be stored collectively in the server. In this case, the administrator does not need to store the user table in the memory 32 of the MFP 10 in advance, and only needs to set the CPU 30 of the MFP 10 to access the user table stored in the server.

(Modification 12) The “function execution device” is not limited to the multi-function device (that is, the MFP 10) that can execute the Scan function, the Print function, and the Copy function, and may be a scanner that can execute only the Scan function. It may be a printer that can execute only the Print function, or a copier that can execute only the Copy function. The “function execution device” is a device (for example, a PC, a server, or a portable terminal) that executes a function (for example, an image display function or a data calculation function) different from the Scan function, the Print function, and the Copy function. Mobile phone, smart phone, PDA, etc.)).

(Modification 13) In each of the above embodiments, each process in FIGS. 2 and 3 is realized by software (that is, a program). At least one of the processes in FIGS. 2 and 3 is a logic circuit or the like. It may be realized by hardware.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology illustrated in the present specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

  2: communication system, 4: LAN, 10, 50, 60, 70, 80: multi-function device (MFP), 12: operation unit, 14: display unit, 16: communication I / F, 18: print execution unit, 20 : Scan execution unit, 22: Control unit, 30: CPU, memory 32, 90: HUB, 100: Authentication server

Claims (10)

A specific function execution device,
A function execution unit that executes at least one function including the first function;
A supply unit that supplies authentication setting information stored in a first memory to an authentication server, the authentication server relating to whether or not the specific function execution device is allowed to participate in a specific network. Executing the authentication using the authentication setting information supplied from the specific function execution device; and
When the authentication succeeds in the authentication server, the first function setting information is stored in a second memory, and when the authentication fails in the authentication server, the first function setting information is stored in the second memory. The first function setting information is a first of the M function execution devices participating in the specific network (where M is an integer equal to or greater than 1). The storage control unit, which is function setting information used by the first function execution device when the function execution device executes the first function;
A function control unit that causes the function execution unit to execute the first function using the first function setting information stored in the second memory;
A specific function execution device comprising: The specific function execution device further includes:
A user information acquisition unit for acquiring user information corresponding to the user;
The storage control unit
In a situation where the first function execution device is used by the first user when the authentication is successful in the authentication server and the first user information corresponding to the first user is acquired. Storing the first function setting information used by the first function execution device in the second memory when executing the first function;
When the authentication is successful in the authentication server and second user information corresponding to a second user different from the first user is acquired, the first function execution device performs the second operation. Storing the second function setting information used by the first function execution device in the second memory when executing the first function in a situation used by a user of
The function controller is
When the first user information is acquired and the first function is to be executed, the function execution unit uses the first function setting information stored in the second memory. To execute the first function,
When the second user information is acquired and the first function is to be executed, the function execution unit uses the second function setting information stored in the second memory. The specific function execution device according to claim 1, which causes the first function to be executed.   The specific function execution device according to claim 2, wherein the user information acquisition unit acquires the user information input by the user when execution of the first function is instructed. The specific function execution device further includes:
The first memory;
The second memory;
A function setting information acquisition unit that acquires the first function setting information from the first function execution device using the specific network when the authentication is successful in the authentication server; Item 4. The specific function execution device according to any one of Items 1 to 3. The at least one function further includes a second function different from the first function,
The storage control unit further includes:
When the authentication is successful in the authentication server, the second function execution device among the M function execution devices is used by the second function execution device when executing the second function. Third function setting information, which is function setting information to be stored in the second memory,
When the authentication fails in the authentication server, the third function setting information is not stored in the second memory,
5. The function control unit according to claim 1, further causing the function execution unit to execute the second function using the third function setting information stored in the second memory. 6. The specific function execution apparatus as described in any one of Claims. The specific function execution device further includes:
When the authentication succeeds in the authentication server, N of the M function execution devices (N is an integer from 1 to M) of the M function execution devices using the specific network. From each, a record information acquisition unit that acquires record information related to the record of execution of the first function;
A selection unit that selects the first function execution device from the N function execution devices based on N pieces of performance information acquired from the N function execution devices;
The storage control unit
When the selected first function execution device executes the first function, the first function setting information used by the first function execution device is stored in the second memory. The specific function execution device according to any one of claims 1 to 5. The M function execution devices are provided by the N function execution devices provided by a first vendor that is a vendor of the specific function execution device, and by a second vendor different from the first vendor. (M-N) function execution devices,
The specific function execution device according to claim 6, wherein the selection unit selects the first function execution device among the N function execution devices provided by the first vendor. The function execution unit includes a reading unit that executes scanning to generate image data,
The first function includes an image processing function for storing image data generated by the reading unit in a predetermined storage area, and the first function setting information is necessary for accessing the predetermined storage area. The specific function execution apparatus as described in any one of Claim 1 to 7 containing various authentication information.   The specific function execution device according to any one of claims 1 to 8, wherein the authentication setting information includes information for the authentication in accordance with an IEEE 802.1x standard. A computer program for a specific function execution device including a function execution unit that executes at least one function including a first function,
In the computer mounted on the specific function execution device, the following processes, that is,
Supply processing for supplying authentication setting information stored in a first memory to an authentication server, the authentication server relating to whether or not the specific function execution device is allowed to participate in a specific network Performing the authentication using the authentication setting information supplied from the specific function execution device;
When the authentication succeeds in the authentication server, the first function setting information is stored in a second memory, and when the authentication fails in the authentication server, the first function setting information is stored in the second memory. The first function setting information is a first of the M function execution devices participating in the specific network (where M is an integer greater than or equal to 1). When the function execution device executes the first function, the storage control process is function setting information used by the first function execution device;
A function control process for causing the function execution unit to execute the first function using the first function setting information stored in the second memory;
A computer program that executes

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