JP2012065256A - Communication apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication apparatus capable of preventing communication information from leaking.SOLUTION: A multifunction machine 10 makes communication information stored in a communication information table TB11, sets a protection level which protects the communication information, generates fictitious information by making at least a part of the communication information fictitious, and makes the information stored in a fictitious information table TB12. The multifunction machine 10 outputs the fictitious information stored in the fictitious information table TB12 and the communication information stored in the communication information table TB11 in a case where it is determined that the information is in a protection level where the leakage is prevented. On the other hand, in a case where it is determined that the information is not in a protection level where the leakage is prevented, the communication information stored in the communication information table TB11 is output. The multifunction machine 10 generates the fictitious information from the communication information in accordance with the protection level.

Description

  The present application relates to a communication apparatus that can effectively prevent leakage of personal information.

  Patent Document 1 discloses a technique for preventing leakage of personal information by replacing and displaying personal information data with fictitious data when a communication device is stolen or lost.

JP 2004-112126 A

  In the communication device, there are cases where another person such as a service person performs remote operation or direct operation on the communication device when supporting an operation method or performing repairs. When another person operates the communication device, the personal information can be prevented from leaking by replacing the personal information data with fictitious data. However, support and repair may require accurate personal information in order to provide appropriate services. In such a case, if the personal information data is replaced with fictitious data, the user may not be able to receive sufficient services. In this specification, the technique which can eliminate such inconvenience is provided.

  In order to achieve this object, the communication device of the present application includes a storage control unit that stores communication information in a storage unit, a setting unit that sets a protection level for protecting communication information, and at least a part of the communication information. Aerialization means for generating aerialization information and storing the aerialization information in the storage unit, a determination means for determining whether or not the protection level prevents leakage of communication information from the communication device, and leakage. If it is determined that the protection level is to be prevented, the aerialization information stored in the storage unit is output. If it is determined that the protection level is not to prevent leakage, the communication stored in the storage unit is output. Output means for outputting information. Further, the aerialization means generates aerialization information from the communication information according to the protection level.

  As an example of the communication device, a multifunction device having functions such as a telephone, a FAX, a scanner, and a printer can be cited. The communication information is information unique to the user. A plurality of types of communication information may exist. A plurality of pieces of communication information may exist for each type. Examples of the communication information include a telephone number of the communication device itself, a telephone number of a communication destination, a mail address, a transmission / reception history, and the like. The aerialization information is generated by rewriting communication information with completely different data. Making a part of communication information aerial includes making a part of the plurality of kinds aerial when there are a plurality of kinds of communication information. Further, a part of one piece of communication information is fictitious (for example, fictitious digits of a telephone number are fictitious). The form in which the output means outputs the communication information or the aerialization information includes a form in which these information is transmitted to other devices by the communication means, and a form in which these information are displayed on the display unit. Further, the fact that the output means outputs the aerialization information does not mean that only the aerialization information is output. This is a concept that does not exclude the case where communication information is output together with the aerialization information.

  The output means outputs communication information when the protection level is not to prevent leakage. As an example of a case where the protection level is not to prevent leakage, there is a case where the user himself / herself uses communication information. On the other hand, the output means outputs the aerialization information when the protection level is to prevent leakage. As an example of the protection level for preventing leakage, there is a case where a serviceman operates the communication device by user support or repair. This makes it possible to partially disclose communication information to others. Therefore, it is possible to achieve both protection of communication information and convenience when receiving support and repair from a service person.

It is a schematic diagram of a support system. It is a figure which shows the operation | movement flowchart (the 1) of a multi-function device. It is a figure which shows the operation | movement flowchart (the 2) of a multi-function device. It is a figure which shows the flowchart of aerialization. It is a figure which shows the operation | movement flowchart of a support center. It is a figure which shows an example of the memory content of a protection level table. It is a figure which shows an example of the memory content of a communication information table. It is a figure which shows an example of the memory content of an aerialization information table. It is a figure which shows an example of the memory content of a setting table.

  Embodiments will be described with reference to the drawings. FIG. 1 shows a schematic diagram of a support system 2 of the present embodiment. The support system 2 includes a multi-function device 10 and a support center 6. The support center 6 includes a PC 70 and a multi-function device 71. The multi-function device 10 and the PC 70 are communicably connected to each other via the Internet 4. The multi-function device 10 and the multi-function device 71 are communicably connected to each other via the telephone line network 5.

  The multi-function device 10 includes a control unit 12, a touch panel 50, a keypad 52, a printing unit 54, a FAX unit 58, a network interface 60, a PSTN interface 62, a scanner unit 64, and the like. The network interface 60 is connected to the Internet 4. The PSTN interface 62 is connected to the telephone line network 5. The touch panel 50 displays various information such as communication information and aerialization information described later. The printing unit 54 prints various data including communication information and aerialization information.

  The control unit 12 includes a CPU 14, a ROM (Read Only Memory) 16, a RAM (Random Access Memory) 30, an NVRAM (Non Volatile RAM) 40, and the like. The CPU 14 executes various processes according to various programs stored in the ROM 16. The basic function program 18 is a program for controlling basic operations of the multi-function device 10. The basic function program 18 includes, for example, various control programs for controlling the printing unit 54, the FAX unit 58, and the like. The RAM 30 stores various data generated in the process of executing the process according to the basic function program 18.

  The NVRAM 40 includes a protection level table TB10, a communication information table TB11, an aerialization information table TB12, and a setting table TB13. FIG. 6 shows an example of the protection level table TB10. The protection level table TB10 is a table that defines the handling of communication information at each stage of the protection level. The protection level is a value that determines a level for protecting communication information. In the protection level table TB10, there are three levels of protection levels from “0” to “2”. The protection level “0” is the lowest level, and all types of communication information are in a normal state. Accordingly, all types of communication information can be freely accessed. As the protection level increases from “1” to “2”, the degree of protection of communication information is increased.

  Further, the protection level table TB10 defines the handling according to the protection level for each type of communication information. The protection level table TB10 includes transmission / reception history 210, name 211, telephone number (individual) 212, telephone number (company) 213, FAX number (individual) 214, FAX number (company) 215, e-mail address (individual) 216, e-mail address. It defines the handling of twelve types of communication information: (company) 217, image (individual) 218, image (common) 219, print history and billing information 220, and password 221. The transmission / reception history 210 is a communication record such as FAX. The name 211 is the name of the communication partner. The image (individual) 218 and the image (common) 219 are various image data. An example of the image data is an image created using the scanner unit 64. The password 221 is various passwords (for example, a password for resetting the protection level of the multi-function device 10).

  In the protection level table TB10, as the protection level increases from “1” to “2”, the number of types of communication information for which aerial information is generated increases. Here, the aerialization information is information generated by replacing at least a part of a character string of communication information with a character string that is randomly generated. As a result, the degree of protection of communication information can be increased as the protection level increases.

  Further, a communication information table TB11 and an aerialization information table TB12 are provided for each of the 12 types of communication information. FIG. 7 shows an example of the communication information table TB11 for the communication information of the transmission / reception history 210. The communication information table TB11 of the transmission / reception history 210 includes seven types of communication information (name 251, telephone number 252, FAX number 253, mail address 254, time information 255, number of pages 256, communication mode 257). The identification number 250 is a serial number assigned to identify each of a plurality of transmission / reception histories. The name 251 is the name of the communication partner. The telephone number 252, the FAX number 253, and the mail address 254 are information necessary for executing communication. The time information 255 is information related to the date and time when communication is executed. The page number 256 is the number of pages when FAX communication is executed. The communication mode 257 is a mode (eg, fine mode, normal mode, etc.) used in FAX communication.

  Each of the remaining 11 types of communication information other than the transmission / reception history 210 also includes a communication information table. However, these configurations are the same as the configuration of the communication information table TB11 for the transmission / reception history 210. Detailed description is omitted here. The registered contents of the communication information table may be registered in advance by a user or the like.

  FIG. 8 shows an example of the aerialization information table TB12 for the aerialization information in the transmission / reception history 210. The fictitious information table TB12 includes storage areas for seven types of fictitious information (name 251a, telephone number 252a, FAX number 253a, mail address 254a, time information 255a, number of pages 256a, communication mode 257a). The aerialization information stored in the aerialization information table TB12 in FIG. 8 is generated from the communication information in the communication information table TB11 in FIG. Further, a method for creating communication information will be described later.

  FIG. 9 shows an example of the setting table TB13. The setting table TB13 includes a local support protection level 300, a support center IP address 302, and a support center FAX number 303. The local support protection level 300 is a protection level set for the multi-function device 10 when local support (support for a serviceman operating the multi-function device 10) described later is executed. In this embodiment, a case where the local support protection level 300 = “1” will be described. The support center IP address 302 is the IP address of the PC 70 that accesses the multi-function device 10 during remote support. The support center FAX number 303 is the FAX number of the multi-function device 71 provided in the support center 6. The support center IP address 302 and the support center FAX number 303 may be stored in the setting table TB13 when the multi-function device 10 is shipped.

  A configuration of the PC 70 provided in the support center 6 will be described. The PC 70 includes a CPU 72, a storage unit 74, a display unit 82, an operation unit 84, a network interface 86, a RAM 90, and the like. The display unit 82 can display various information. The operation unit 84 is configured by a keyboard and a mouse. The network interface 86 can communicate various information with the multi-function device 10 via the Internet 4.

  The storage unit 74 stores a basic program 76. The basic program 76 is a program for controlling basic operations of the PC 70. The PC 70 of the support center 6 is connected to the multi-function device 10 via the Internet 4. The PC 70 performs remote support such as failure analysis by remotely operating the multi-function device 10. The remote support by the PC 70 can be automatically performed by the basic program 76. The PC 70 can also download various types of data from the multi-function device 10 and perform failure analysis of the multi-function device 10 using the acquired data.

  The operation content of the support process performed for the multi-function device 10 will be described with reference to the flowcharts of FIGS. The flow in FIG. 2 is a flow that starts when the multi-function device 10 is powered on. At the start of the flow, the protection level is set to “0”. In S11, the CPU 14 determines whether a remote connection request has been received. The remote connection is a process for receiving support such as error cancellation of the multi-function device 10 by having the multi-function device 10 remotely operated from the support center 6 via the Internet 4. If a remote connection request has not been received (S11: NO), the process proceeds to S13, and if received (S11: YES), the process proceeds to S21.

  In S <b> 21, the CPU 14 determines whether or not the source IP address of the remote connection request is the IP address of the support center 6. This determination is made based on whether or not the IP address included in the remote connection request matches the support center IP address 302 stored in the setting table TB13. If it is not the IP address of the support center 6 (S21: NO), it is determined that the access is unauthorized to the multi-function device 10, and the process returns to S11. As a result, when unauthorized access to the multi-function device 10 is detected, it is possible to reliably protect communication information by ignoring the access.

  On the other hand, when the source IP address of the remote connection request is the IP address of the support center 6 in S21 (S21: YES), the process proceeds to S23. In S <b> 23, the CPU 14 receives the remote support protection level from the support center 6. The remote support protection level is set as the communication information protection level of the multi-function device 10. In this embodiment, as an example, a case where the protection level at the time of remote support is “1” and the protection level of communication information is set to “1” will be described.

  In S <b> 26, the CPU 14 determines whether or not transmission of communication information is requested from the support center 6. When transmission of communication information is not requested (S26: NO), it is determined that information that does not require protection (such as the serial number of the multi-function device 10) is requested. Therefore, it progresses to S35 and transmits such information to a support center. On the other hand, if transmission of communication information is requested (S26: YES), the process proceeds to S27.

  In S <b> 27, the CPU 14 determines whether to generate aerial information from the communication information. The determination is a case where the type of communication information requested to be transmitted and the protection level value of the communication information are applied to the protection level table TB10 and the aerialization information is generated for the type of communication information requested to be transmitted. This is done by judging whether or not. When the aerialization information is not generated from the communication information (S27: NO), the process proceeds to S35, and when it is generated (S27: YES), the process proceeds to S31. In this embodiment, as an example, a case where a transmission request for communication information of the transmission / reception history 210 is made from the support center 6 will be described. In this case, when the communication information of the transmission / reception history 210 and the protection level “1” are applied to the protection level table TB10 (FIG. 6), it is determined that the fictitious information is generated from the transmission / reception history 210. Therefore, it progresses to S31.

  In S31, the CPU 14 generates aerialization information from the communication information. The aerialization process performed in S31 will be described using the flow of FIG. In S213, the CPU 14 determines whether or not the protection level of the current communication information is “0”. If the protection level is “0” (S213: YES), the flow ends. If it is not “0” (S213: NO), the process proceeds to S215.

  In S215, the CPU 14 determines whether or not the protection level of the current communication information is “1”. When the protection level is “1” (S215: YES), the process proceeds to S217. In S217, the CPU 14 generates aerial information from the communication information in accordance with the protection level “1”. In step S222, the CPU 14 stores the aerialization information in the aerialization information table TB12.

  On the other hand, in S215, when the protection level is not “1” (S215: NO), it is determined that the protection level is “2”, and the process proceeds to S221. In S221, the CPU 14 generates aerial information from the communication information in accordance with the protection level “2”. In step S222, the CPU 14 stores the aerialization information in the aerialization information table TB12.

  In the present embodiment, as an example, a case will be described in which the aerialization information corresponding to the protection level “1” is generated using the communication information of the transmission / reception history 210. Specifically, the case where the aerialization information stored in the aerialization information table TB12 (FIG. 8) is generated using the communication information table TB11 (FIG. 7) of the transmission / reception history 210 will be described. In the case of the protection level “1”, as shown in the transmission / reception history 210 column of the protection level table TB10 of FIG. 252, FAX number 253, mail address 25) are generated.

  When generating the fictitious information from the communication information of the name 251, the name is replaced with a fictitious name having the same number of characters. In this embodiment, the name 251a “EFG” (FIG. 8) of the aerialization information is generated from the name 251 “ABC” (FIG. 7) of the communication information.

  When generating the fictitious information from the communication information of the telephone number 252, the lower digits of the telephone number are replaced with a fictitious number. By leaving the first few digits of the telephone number without being replaced, the attribute of the telephone number can be left. Examples of telephone number attributes include the type of telephone line and the destination area. For example, when the upper digit of the telephone number is “090” or “080”, it can be seen that the type of the telephone line is a mobile phone, and when it is “050”, the type of the telephone line is an IP phone. If the digit above the phone number is “03”, the call destination area is Tokyo, and if “010”, the call destination area is overseas. In the present embodiment, the telephone number 252a “03-9976-5432” (FIG. 8) of the fictitious information is generated from the telephone number 252 “03-1234-5678” (FIG. 7) of the communication information. By leaving the digits above the telephone number in this way, it is possible to generate fictitious information while leaving the attribute of the telephone number (destination area: Tokyo). Further, from the FAX number 253 “03-1234-5555” (FIG. 7) of the communication information, the FAX number 253a “03-9876-4444” (FIG. 8) of the aerialization information is also generated. It should be noted that the number of digits to be replaced at the time of aerialization can be set as appropriate by the user. The more digits that can be replaced, the higher the confidentiality, but the less likely the attributes remain.

  When generating the fictitious information from the communication information of the mail address 254, the character string in the local part is replaced with a fictitious character string. By leaving the domain of the email address without replacing it, the attribute of the email address can be left. Examples of mail address attributes include country, organization type, and organization name. In this embodiment, the mail address 254a “QRS@abc.co.jp” (FIG. 8) of the fictitious information is generated from the mail address 254 “LMN@abc.co.jp” (FIG. 7) of the communication information. .

  When the transmission / reception history 210 is hypothesized according to the protection level “2”, the hypothetical information is also generated from the communication information of the time information 255, the number of pages 256, and the communication mode 257. When the aerialization information is generated from the communication information of the time information 255, the date and time when the communication is executed is changed to a random date and time. When generating the fictitious information from the communication information of the number of pages 256, the number of pages on which the FAX communication is performed is changed to a random value. When generating the aerial information from the communication information of the communication mode 257, the mode used in the FAX communication is randomly changed.

  In S223, the CPU 14 determines whether or not to execute a communication test. This determination is made by detecting whether a command for executing a communication test has been input via the touch panel 50. The communication test is a test for actually transmitting FAX data to an external device via the telephone line network 5. When the communication test is not executed (S223: NO), S225 is skipped and the process proceeds to S35 (FIG. 2), and when the communication test is executed (S223: YES), the process proceeds to S225. In S225, the CPU 14 reads the support center FAX number 303 from the setting table TB13 and sets it to the FAX data transmission destination FAX number. Then, the FAX data is transmitted to the multi-function device 71 of the support center 6. As a result, when the communication test is executed, the data transmission destination can be the support center 6, so that it is possible to reliably determine whether or not the communication test is successful. When the communication test ends, the process proceeds to S35 (FIG. 2).

  In S <b> 35, the CPU 14 transmits the information requested to be transmitted from the support center 6 to the support center 6 via the Internet 4. At this time, for information that needs to be aerialized, the aerialization information is read from the aerialization information table TB12 and transmitted to the support center 6. On the other hand, for information that does not require aerialization, communication information is read from the communication information table TB11 and transmitted to the support center 6. In this embodiment, as an example, a case where the protection level is “1” is described. Therefore, the aerialization information table TB12 (FIG. 8) reads out the aerialization information (name 251a to e-mail address 254a) and the communication information (time information 255 to communication mode 257) from the communication information table TB11 (FIG. 7). It is. The read aerialization information and communication information are transmitted to the support center 6 (S35).

  In S <b> 37, the CPU 14 determines whether or not a protection level change request has been received from the support center 6. If not received (S37: NO), the process proceeds to S43, the communication information protection level is returned to "0", and the process returns to S11. On the other hand, if a protection level change request is received in S37 (S37: YES), the process proceeds to S39. In S39, the CPU 14 determines whether or not the protection level may be changed. Specifically, a message “Can I change the protection level according to a request from the support center 6?” Is displayed on the touch panel 50, and a user input is awaited. If it is input that the change is not permitted (S39: NO), the process proceeds to S43, the protection level of the communication information is returned to “0”, and the process returns to S11. On the other hand, if a change permission is input (S39: YES), the process proceeds to S41.

  In S41, the CPU 14 changes the protection level. For example, when the protection level is “2” and the protection level change request for reducing the protection level by one level is received, the protection level is changed to “1”. Further, the CPU 14 transmits response information indicating that the protection level has been changed to the PC 70 of the support center 6. Then, the process returns to S26. Thereafter, in S31, the aerialization information is regenerated using the changed protection level. In S35, the aerialization information and the communication information are transmitted to the support center 6 based on the changed protection level.

  As a result, the ratio between the aerialization information and the communication information can be dynamically changed. Therefore, when the multi-function device 10 is remotely operated from the support center 6, it is necessary to make the ratio of communication information higher than the ratio of the aerial information because of the need for more advanced support and repair. Even in such a case, it is possible to respond appropriately.

  Next, the operation of the multi-function device 10 when the service person operates the multi-function device 10 will be described. In S11, when the start operation of the remote support process by the user is not accepted (S11: NO), the process proceeds to S13. In S <b> 13, the CPU 14 determines whether or not the service person has operated the multi-function device 10. As an example of the determination method, there is a method in which a button for selecting whether the operator of the multi-function device 10 is a user or a serviceman is displayed on the touch panel 50 and an input from the operator is waited for.

  If it is determined that the service person is not operating (S13: NO), the process proceeds to S15. In S <b> 15, the CPU 14 determines whether an operation for the multi-function device 10 has been received. If not received (S15: NO), the process returns to S11. On the other hand, if it is received (S15: YES), it is determined that the user is performing an operation, and the process proceeds to S17. In S17, since the protection level is “0”, the CPU 14 reads the communication information from the communication information table TB11 and displays it on the touch panel 50.

  On the other hand, if it is determined in S13 that the serviceman is operating (S13: YES), it is determined that the serviceman is visiting the user side to support the multi-function device 10. The Accordingly, the process proceeds to S109 (FIG. 3), and the protection level of the communication information is changed from the current level (“0”) to the local support protection level 300 stored in the setting table TB13. Then, the process proceeds to S111.

  In S111, the CPU 14 generates aerial information from the communication information according to the protection level. Note that the content of the method for generating the aerialization information is the same as the flow content of FIG. 4, and thus detailed description thereof is omitted here. In S <b> 115, the CPU 14 determines whether an operation input for displaying communication information on the panel has been received via the touch panel 50. If not accepted (S115: NO), S117 is skipped and the process proceeds to S121. If accepted (S115: YES), the process proceeds to S117. In S <b> 117, the CPU 14 displays the aerial information (including the case where the aerial information and communication information are mixed) on the touch panel 50.

  Thereby, when the protection level of the communication information is set to “1” or “2”, the aerial information (including the case where the aerial information and the communication information are mixed) is displayed on the touch panel 50 in S117. When the communication information protection level is set to “0”, the communication information can be output to the touch panel 50 in S17. Therefore, when the user operates the multi-function device 10 while looking at the touch panel 50, the communication information that is correct information is displayed on the display unit, so that the operability does not deteriorate. On the other hand, when the service person operates the multi-function device 10 while looking at the touch panel 50, the aerial information (including the case where the aerial information and communication information are mixed) is displayed on the touch panel 50. Information leakage can be prevented.

  In S121, the CPU 14 determines whether or not a command for printing the communication management report has been input. The communication management report is data for confirming the communication history, and includes various communication information. If the command to print the communication management report has not been input (S121: NO), the process proceeds to S150. In S150, the CPU 14 determines whether or not the operation of the multi-function device 10 by the service person has ended. As an example of a method for detecting the end of the operation, there is a method for determining the end of the operation when a password for resetting the protection level of the multi-function device 10 to “0” is input via the keypad 52. When the serviceman's operation is completed (S150: YES), the process proceeds to S153, the protection level of the communication information is returned to “0”, and the process returns to S11 (FIG. 2). On the other hand, when the operation of the service person has not ended (S150: NO), the process returns to S115.

  In S121, when a command to print the communication management report is input (S121: YES), the process proceeds to S123. In S123, the CPU 14 determines whether or not the protection level of the communication information is “0”. If it is “0” (S123: YES), the process proceeds to S125, and the CPU 14 prints a communication management report including communication information. Then, the process proceeds to S150. On the other hand, when the protection level is not “0” (S123: NO), the process proceeds to S135.

  In S135, the CPU 14 determines whether or not the protection level of the communication information is “2”. When the protection level is not “2” (S135: NO), it is determined that the protection level is “1”, and the process proceeds to S139. In S139, the CPU 14 uses the communication information included in the communication management report to generate fictitious information when the protection level is “1” (for example, in the transmission / reception history 210, the name 251, For the telephone number 252, FAX number 253, mail address 254), the fictitious information is generated. Then, the process proceeds to S141. On the other hand, if the protection level is “2” in S135 (S135: YES), the process proceeds to S137. In S <b> 137, the CPU 14 includes communication information that needs to generate fictitious information when the protection level is “2” among the communication information included in the communication management report (for example, in the transmission / reception history 210, the name 251, For the telephone number 252, FAX number 253, mail address 254, time information 255, number of pages 256, communication mode 257), the fictitious information is generated. Then, the process proceeds to S141. In S141, the CPU 14 prints a communication management report having the aerial information (including a case where the aerial information and communication information are mixed). Then, the process returns to S135.

  Thereby, even when the communication management report is printed, if the protection level is set to “1” or “2”, the aerial information (including the case where the aerial information and communication information are mixed) is included. ), The communication management report can be printed. Therefore, leakage of communication information can be prevented.

  Next, the contents of the remote support process performed by the PC 70 of the support center 6 will be described with reference to FIG. The flow of FIG. 5 is started in response to the support program being activated on the PC 70. In S309, the CPU 72 executes a support process. The support process includes various processes such as a process for remotely operating the multi-function device 10 and a process for analyzing the cause of an error in the multi-function device 10. In S <b> 311, the CPU 72 determines whether it is necessary to transmit a remote connection request to the multi-function device 10. This determination is made based on whether or not remote control of the multi-function device 10 is necessary in order to perform support such as error analysis of the multi-function device 10. When it is not necessary to transmit (S311: NO), the process proceeds to S317, and when it is necessary to transmit (S311: YES), the process proceeds to S313. In S <b> 313, the CPU 72 transmits a remote connection request and a remote support protection level to the multi-function device 10. In S <b> 315, the CPU 72 receives information transmitted from the multi-function device 10.

  In S317, the CPU 72 determines whether or not to end the support process. The determination may be, for example, that the support process is continued when the cause of the error cannot be determined, and the support process is terminated when the cause of the error can be determined. If the process ends (S317: YES), the flow ends. If the process does not end (S317: NO), the process proceeds to S319.

  In S319, the CPU 72 determines whether or not the remote support process can be continued at the current remote support protection level. If it is determined that the process can be continued (S319: YES), the process returns to S309. On the other hand, if it is determined that continuation is not possible (S319: NO), the process proceeds to S323. As an example of the case where the remote support process cannot be continued, when the FAX number aerial information is being picked up from the multi-function device 10, accurate information of the FAX number is required to identify the communication error content. And so on.

  In S <b> 323, the CPU 72 transmits a communication information protection level change request to the multi-function device 10. In S324, the CPU 72 determines whether or not response information (S41) to the protection level change request has been received from the multi-function device 10 within a predetermined time. If not received (S324: NO), the process returns to S309, and if received (S324: YES), the process proceeds to S325. In S325, the CPU 72 determines whether or not the remote support process can be continued with the changed protection level. In this determination, for example, when the communication information of the FAX number can be obtained instead of the fictitious information of the FAX number, it may be determined that the remote support process can be continued. If it is determined that the remote support process cannot be continued (S325: NO), the process returns to S323, and if it is determined that the remote support process is possible (S325: YES), the process proceeds to S327. In S <b> 327, the CPU 72 stores the changed protection level in the storage unit 74. Then, the process returns to S309, and the CPU 72 continues the remote support process.

  The effect of the multi-function device 10 according to the present embodiment will be described. In the multi-function device 10 of the present application, when the user himself / herself uses communication information, the protection level of the communication information is not set to “1” or “2”. As a result, when the user operates the multi-function device 10, communication information that is correct information is displayed on the touch panel 50, so that the operability does not deteriorate. On the other hand, when the PC 70 or the service person of the support center 6 uses the communication information, the protection level of the communication information is set to “1” or “2”. In this case, the aerial information (including the case where the aerial information and communication information are mixed) is transmitted to the support center 6 or displayed on the touch panel 50. Thereby, leakage of communication information can be prevented. Therefore, it is possible to achieve both protection of communication information and convenience when receiving support and repair.

  Moreover, the ratio of the communication information used as the production | generation object of overhead information among communication information is controlled according to the protection level. Therefore, the degree of protection of communication information can be controlled in multiple stages according to the protection level.

  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 types of communication information are not limited to the twelve types shown in FIG. 6, and the configuration of the present application can be applied even when there are many types of communication information. Further, the level of protection level is not limited to the three levels “0” to “2” shown in FIG. By creating more stages according to the protection level, the degree of protection of communication information can be controlled more finely.

  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.

  The multi-function device 10 is an example of a communication device. The name 251 through the communication mode 257 are examples of communication information. The NVRAM 40 is an example of a storage unit. The name 251a or the communication mode 257a is an example of fictitious information. The touch panel 50 is an example of a display unit. The PC 70 is an example of an external device.

  Moreover, the control part which performs S23 and S41 is an example of a setting means. The control unit that executes S31, S213, S215, and S219 is an example of an aerialization unit. The control unit that executes S11 and S13 is an example of a determination unit. The control unit that executes S17, S35, S113, S117, S125, and S141 is an example of an output unit. The control unit that executes S39 is an example of a determination unit.

  10: Multi-function device, 14 and 72: CPU, 70: PC, 40: NVRAM, 50: Touch panel, 210: Transmission / reception history, 251: Name, 252: Telephone number, 253: FAX number, 254: Mail address, TB10: Protection level table, TB11: communication information table, TB12: aerialization information table, TB13: setting table

Claims (6)

A communication device,
Storage control means for storing communication information in the storage unit;
Setting means for setting a protection level for protecting the communication information;
Aerialization means for aerializing at least part of the communication information to generate aerialization information and storing the aerialization information in the storage unit;
Determining means for determining whether or not the communication information is at a protection level for preventing leakage of the communication information from the communication device;
When it is determined that the protection level is to prevent the leakage, the aerialization information stored in the storage unit is output, and when it is determined that the protection level is not to prevent the leakage, the storage is performed. Output means for outputting the communication information stored in the unit;
With
The aerialization means generates the aerialization information from the communication information according to the protection level.
A communication device. A display unit for displaying the communication information and the aerialization information;
The output means includes
In response to accepting an output command to output the communication information to an external device when the protection level is to prevent the leakage, the aerialization information is transmitted to the external device,
2. The communication information is displayed on the display unit in response to receiving an output command to output the communication information to the display unit when the protection level is not to prevent the leakage. The communication apparatus as described in. When receiving a request to change the protection level from the external device, further comprising a determination means for determining whether to permit the change of the protection level,
The setting means changes the protection level on condition that the change of the protection level is permitted by the determination means,
The aerialization means regenerates the aerialization information based on the protection level after the change,
The communication apparatus according to claim 1, wherein the output unit retransmits the regenerated aerial information to the external apparatus. A display unit for displaying the communication information and the aerialization information;
The output means includes
When the protection level is to prevent the leakage, in response to receiving an output command to output the communication information to the display unit, the aerialization information is displayed on the display unit,
The communication information is displayed on the display unit in response to receiving an output command for outputting the communication information to the display unit when the protection level is not the leakage prevention level. The communication apparatus according to 1. A printing unit for printing the communication information and the aerialization information;
The output means includes
When the protection level is to prevent the leakage, in response to receiving an output command to output the communication information to the printing unit, the aerialization information is printed by the printing unit,
The communication information is printed by the printing unit in response to receiving an output command to output the communication information to the printing unit when the protection level is not the leakage prevention level. 4. The communication device according to 4. The communication information includes a plurality of types,
The said aerialization means increases the number of the types of the said communication information which produce | generate the said aerialization information according to the said protection level becoming high. Any one of Claim 1 thru | or 5 characterized by the above-mentioned. The communication device described.

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