JP6205305B2 - Maintenance server, table update program, and table update method - Google Patents

Description

  The present invention relates to a maintenance server, a table update program, and a table update method.

  There is “remote maintenance” as a technique for maintaining a terminal device located away from a maintenance worker. In remote maintenance, a maintenance worker performs maintenance such as changing the settings of a terminal device and troubleshooting, using a maintenance server connected to the terminal device via a network. Information on the terminal device to be subjected to remote maintenance is registered in the maintenance table. The terminal device information includes a terminal ID and an IP address. The maintenance server performs remote maintenance for the terminal devices registered in the maintenance table. Conventionally, each time a new terminal device is installed, the maintenance worker manually registers the terminal device information in the maintenance table, and whenever the terminal device is removed, the corresponding terminal device information is manually retrieved from the maintenance table. It was deleted.

JP 2008-293258 A

  As a terminal device subject to remote maintenance, there is an “ATM (Automated Teller Machine) terminal” in a bank online system. In recent years, ATM terminals have been installed in convenience stores and station concourses in addition to bank stores, and the number of newly installed ATM terminals is increasing. In recent years, ATM terminals have been frequently established and removed with the integration and closure of bank stores, the opening and closing of convenience stores, and the reconstruction of stores that meet customer needs. Under such circumstances, conventionally, registration of ATM terminal information to the maintenance table and deletion from the maintenance table have been performed manually by a maintenance worker. Registration / deletion is done manually. As the number of ATM terminals to be newly installed or removed increases, or as the frequency of new establishment or removal of ATM terminals increases, the burden on maintenance workers increases and registration becomes necessary. It was easy to make mistakes and deletion mistakes.

  The disclosed technology has been made in view of the above, a maintenance server, a table update program, and a table update method capable of reducing the work burden of a maintenance worker and preventing terminal information registration errors and deletion errors. The purpose is to provide.

  The maintenance server includes a table in which information on a target terminal that is a target of remote maintenance is registered, and an update unit that updates the table. The update unit updates the table on a daily basis based on information transmitted from the terminal device when the terminal device is activated, and uses the first terminal device operating on the time as the target terminal as the table. On the other hand, the second terminal device not operating on time is not included in the table.

  According to the disclosed aspect, it is possible to reduce the work burden on the maintenance worker and prevent terminal information registration mistakes and deletion mistakes.

FIG. 1 is a diagram illustrating a configuration example of a remote maintenance system according to the first embodiment. FIG. 2 is a functional block diagram illustrating an example of the ATM terminal according to the first embodiment. FIG. 3 is a diagram illustrating an example of terminal information according to the first embodiment. FIG. 4 is a functional block diagram illustrating an example of the maintenance server according to the first embodiment. FIG. 5 is a diagram illustrating an example of a maintenance table according to the first embodiment. FIG. 6 is a diagram for explaining the operation of the remote maintenance system according to the first embodiment. FIG. 7 is a flowchart for explaining processing of the maintenance server according to the first embodiment. FIG. 8 is a functional block diagram illustrating an example of a maintenance server according to the second embodiment. FIG. 9 is a diagram for explaining the operation of the remote maintenance system according to the second embodiment. FIG. 10 is a flowchart for explaining the processing of the maintenance server according to the second embodiment. FIG. 11 is a diagram illustrating a hardware configuration example of the maintenance server. FIG. 12 is a diagram illustrating a hardware configuration example of the ATM terminal.

  Embodiments of a maintenance server, a table update program, and a table update method disclosed in the present application will be described below in detail with reference to the drawings. The embodiment does not limit the maintenance server, the table update program, and the table update method disclosed in the present application. Moreover, the same code | symbol is attached | subjected to the structure which has the same function in each Example, and the step which performs the same process, and the overlapping description is abbreviate | omitted.

  In the following embodiments, an ATM terminal will be described as an example of a terminal device to be subjected to remote maintenance. However, a terminal device to which the disclosed technology is applicable is not limited to an ATM terminal. The disclosed technology can be applied to any terminal device having a communication function.

[Example 1]
<Configuration of remote maintenance system>
FIG. 1 is a diagram illustrating a configuration example of a remote maintenance system according to the first embodiment. A remote maintenance system 1 shown in FIG. 1 includes a maintenance server 10 and ATM terminals 20-1 to 20-3. The maintenance server 10 and the ATM terminals 20-1 to 20-3 are connected via the network 30.

  Below, when not distinguishing ATM terminal 20-1-20-3, it may be named the ATM terminal 20 generically. In FIG. 1, three ATM terminals are taken as an example, but the number of ATM terminals that can be connected to the maintenance server 10 is not limited to three.

<Configuration of ATM terminal>
FIG. 2 is a functional block diagram illustrating an example of the ATM terminal according to the first embodiment. The ATM terminal 20 shown in FIG. 2 includes a terminal information storage unit 21, a terminal information acquisition unit 22, a communication unit 23 connected to the network 30, and a maintenance execution unit 24.

  The terminal information storage unit 21 stores terminal information of the ATM terminal 20. FIG. 3 is a diagram illustrating an example of terminal information according to the first embodiment. As shown in FIG. 3, the terminal information includes a terminal ID, an IP address, a bank code, a store number, a machine number, and a model code. The terminal ID is an ID that uniquely identifies each of the ATM terminals 20-1 to 20-3. The IP address is different for each ATM terminal 20-1 to 20-3 and indicates the destination of the control command transmitted from the maintenance server 10. The bank code is different for each financial institution. The store number identifies the store or place where the ATM terminals 20-1 to 20-3 are installed. The machine number is a different number assigned to each of the plurality of ATM terminals 20 in the same store. The model code is a code that identifies each model of the ATM terminals 20-1 to 20-3. The terminal information is individually set for each ATM terminal when each of the ATM terminals 20-1 to 20-3 is installed, and is stored in the terminal information storage unit 21.

  The terminal information acquisition unit 22 acquires terminal information from the terminal information storage unit 21 when the ATM terminal 20 is activated, and outputs the acquired terminal information to the communication unit 23.

  The communication unit 23 transmits the terminal information input from the terminal information acquisition unit 22 to the maintenance server 10 via the network 30. In addition, the communication unit 23 receives the control command transmitted from the maintenance server 10 via the network 30, and outputs the received control command to the maintenance execution unit 24.

  The maintenance execution unit 24 performs various types of maintenance of the ATM terminal 20 according to the control command input from the communication unit 23. For example, the maintenance execution unit 24 modifies software stored in the ATM terminal 20 according to the control command.

<Configuration of maintenance server>
FIG. 4 is a functional block diagram illustrating an example of the maintenance server according to the first embodiment. The maintenance server 10 illustrated in FIG. 4 includes a communication unit 11, a table update unit 12, a maintenance table storage unit 13, and a command issue unit 14 connected to the network 30.

  The communication unit 11 receives terminal information respectively transmitted from the ATM terminals 20-1 to 20-3 via the network 30 and outputs the received terminal information to the table update unit 12. The communication unit 11 transmits the control command input from the command issuing unit 14 to each of the ATM terminals 20-1 to 20-3 via the network 30 according to the IP address.

  The maintenance table storage unit 13 stores a maintenance table. FIG. 5 is a diagram illustrating an example of a maintenance table according to the first embodiment. Here, the terminal ID of ATM 20-1 is “ATM1”, the terminal ID of ATM 20-2 is “ATM2”, and the terminal ID of ATM 20-3 is “ATM3”. The ATM terminal 20 registered in the maintenance table is a target of remote maintenance. In the maintenance table shown in FIG. 5, the “operation flag” takes a value of “1” or “0” and indicates the operation status of the ATM terminal 20 on a daily basis. That is, at a certain time on a certain day, the operating flag of the ATM terminal 20 that is operating with the power turned on is “1”, and the ATM that has been powered off or has been removed and is not operating. The operation flag of the terminal 20 is “0”.

  The table update unit 12 updates the maintenance table stored in the maintenance table storage unit 13 based on the terminal information input from the communication unit 11.

  The command issuing unit 14 issues a control command for remote maintenance. When issuing a control command, the command issuing unit 14 refers to the maintenance table stored in the maintenance table storage unit 13 and acquires each IP address of the ATM terminals 20-1 to 20-3 from the maintenance table. The command issuing unit 14 adds each IP address as a header to the control command, and outputs the control command after adding the IP address to the communication unit 11.

<Remote maintenance system operation>
FIG. 6 is a diagram for explaining the operation of the remote maintenance system according to the first embodiment. In FIG. 6, the update status of the maintenance table is shown in time series. In the maintenance table in FIG. 6, only the terminal ID and the operation flag are shown among the items in the maintenance table for the sake of brevity. ATM1 corresponds to the ATM terminal 20-1, ATM2 corresponds to the ATM terminal 20-2, and ATM3 corresponds to the ATM terminal 20-3. Each time in FIG. 6 is displayed for 24 hours.

  At 16:00 on March 1, ATM1, ATM2, and ATM3 were newly established. ATM1 and ATM2 are installed in a bank store, and the operating hours of ATM1 and ATM2 are from 8:00 to 22:00. For this reason, the power supply of ATM1 and ATM2 is set to be automatically turned on at 8 o'clock every day and automatically turned off at 22 o'clock every day. On the other hand, ATM3 is installed in a 24-hour convenience store and is a 24-hour ATM. For this reason, ATM3 is set to restart at 2 o'clock every day.

  When the ATM 3 whose power is turned on at 2 o'clock on March 2 is started and communicates with the maintenance server 10, the ATM 3 transmits the terminal information of its own terminal to the maintenance server 10. In the maintenance server 10 that has received the ATM3 terminal information, the table updating unit 12 registers the ATM3 terminal information in the maintenance table. In addition, the table update unit 12 sets the operation flag of ATM3 to “1”.

  The ATMs 1 and 2 that are turned on at 8 o'clock on March 2 transmit terminal information of their own terminals to the maintenance server 10 when communication with the maintenance server 10 is established after startup. In the maintenance server 10 that has received the ATM1 and ATM2 terminal information, the table updating unit 12 adds the ATM1 terminal information and the ATM2 terminal information to the maintenance table. The table updating unit 12 sets the operation flags of ATM1 and ATM2 to “1”.

  The table updating unit 12 deletes the terminal information whose operation flag is “0” from the maintenance table at 10 o'clock every day, and then resets the operation flags of the remaining terminal information to “0”. At 10:00 on March 2, there are no terminal information deleted from the maintenance table because the operation flags of ATM1, ATM2, and ATM3 are all "1". Therefore, the table update unit 12 resets the operation flags of ATM1, ATM2, and ATM3 to “0” at 10:00 on March 2.

  At 22:00 on March 2, ATM1 and ATM2 are turned off.

  The ATM 3 restarted at 2 o'clock on March 3 transmits terminal information of its own terminal to the maintenance server 10 when communication with the maintenance server 10 is established after startup. In the maintenance server 10 that has received the ATM3 terminal information, the table update unit 12 updates the ATM3 operation flag from “0” to “1” because the ATM3 terminal information with the operation flag “0” exists in the maintenance table. To do.

  Here, the start time of ATM 2 on March 3 was changed from 8 o'clock to 14:00 due to the occurrence of a special schedule.

  Therefore, at 8 o'clock on March 3, only the power source of ATM1 of ATM1 and ATM2 is turned on. The ATM 1 that is turned on transmits terminal information of its own terminal to the maintenance server 10 when communication with the maintenance server 10 is established after startup. In the maintenance server 10 that has received ATM1 terminal information, the table updating unit 12 updates the ATM1 operation flag from “0” to “1” because the ATM1 terminal information with the operation flag “0” exists in the maintenance table. To do.

  Therefore, at 10:00 on March 3, the operating flags of ATM1 and ATM3 are “1”, while the operating flag of ATM2 is “0”. Therefore, the table updating unit 12 deletes ATM2 terminal information from the maintenance table at 10:00 on March 3. Further, the table updating unit 12 resets the operation flags of ATM1 and ATM3 to “0” after deleting the terminal information of ATM2.

  At 2 o'clock on March 3, ATM2 is turned on. When the ATM 2 that has been turned on is activated and establishes communication with the maintenance server 10, the ATM 2 transmits its terminal information to the maintenance server 10. In the maintenance server 10 that has received the ATM2 terminal information, the table updating unit 12 checks whether or not the ATM2 terminal information exists in the maintenance table. Here, since the ATM2 terminal information does not exist in the maintenance table, the table update unit 12 adds the ATM2 terminal information to the maintenance table. In addition, the table update unit 12 sets the operation flag of ATM2 to “1”.

  At 22:00 on March 3, ATM1 and ATM2 are turned off.

  The ATM 3 restarted at 2 o'clock on March 4 transmits terminal information of its own terminal to the maintenance server 10 when communication with the maintenance server 10 is established after startup. In the maintenance server 10 that has received the ATM3 terminal information, the table update unit 12 updates the ATM3 operation flag from “0” to “1” because the ATM3 terminal information with the operation flag “0” exists in the maintenance table. To do.

  At 8 o'clock on March 4, ATM1 and ATM2 are turned on. The ATM 1 and ATM 2 that are turned on transmit terminal information of their own terminals to the maintenance server 10 when communication with the maintenance server 10 is established after activation. In the maintenance server 10 that has received the ATM1 and ATM2 terminal information, the table updating unit 12 changes the ATM1 operation flag from “0” to “1” because the ATM1 terminal information with the operation flag “0” exists in the maintenance table. Update to Further, since the ATM2 terminal information with the operation flag “1” exists in the maintenance table, the table update unit 12 maintains the ATM2 operation flag with “1”.

  At 10:00 on March 4, there are no terminal information deleted from the maintenance table because the operation flags of ATM1, ATM2, and ATM3 are all "1". Therefore, the table updating unit 12 resets the operation flags of ATM1, ATM2, and ATM3 to “0” at 10:00 on March 4.

  Therefore, from 10:00 on March 2 to 10:00 on March 3, ATM1, ATM2, and ATM3 that are operating at 10:00 on March 2 are included in the maintenance table, so ATM1, ATM2, and ATM3 are Subject to remote maintenance. Also, from 10:00 on March 3 to 14:00 on March 3, ATM1 and ATM3 operating at 10:00 on March 3 are included in the maintenance table, so ATM1 and ATM3 are subject to remote maintenance. It becomes. Since ATM2 is added to the maintenance table at 13:00 on March 3, ATM1, ATM2, and ATM3 are targeted for remote maintenance from 14:00 on March 3 to 10:00 on March 4.

<Maintenance server processing>
FIG. 7 is a flowchart for explaining processing of the maintenance server according to the first embodiment. The flowchart shown in FIG. 7 starts when the power of the maintenance server 10 is turned on and ends when the maintenance server 10 is turned off.

  The table updating unit 12 determines whether or not the current time is on-time (step S01). If the current time is not on time (step S01: No), the process proceeds to step S05.

  When the current time is on-time (step S01: Yes), the table updating unit 12 checks the operation flag of each terminal information registered in the maintenance table (step S02). Then, the table updating unit 12 deletes the terminal information whose operation flag is “0” from the maintenance table (step S03), and then resets the operation flag of the terminal information remaining in the maintenance table from “1” to “0”. (Step S04).

  Next, the table update unit 12 determines whether or not terminal information has been received, that is, whether or not terminal information has been input from the communication unit 11 (step S05). When the terminal information is not received (step S05: No), the process returns to step S01.

  When the terminal information is received (step S05: Yes), the table updating unit 12 determines whether or not the terminal ID of the received terminal information exists in the maintenance table (step S06).

  When the terminal ID of the received terminal information exists in the maintenance table (step S06: Yes), the table update unit 12 updates the operation flag corresponding to the terminal ID to “1” (step S07). After updating the operation flag, the process returns to step S01.

  When the terminal ID of the received terminal information does not exist in the maintenance table (step S06: No), the table updating unit 12 adds the terminal information to the maintenance table and sets the operation flag corresponding to the terminal information to “ 1 "(step S08). After the terminal information is added to the maintenance table, the process returns to step S01.

[Example 2]
In the second embodiment, the configuration of the remote maintenance system and the configuration of the ATM terminal are the same as those in the first embodiment, and thus description thereof is omitted. However, the maintenance table of the second embodiment is obtained by deleting the item “operation flag” from the maintenance table illustrated in FIG. 5. In the second embodiment, the configuration of the maintenance server, the operation of the remote maintenance system, and the processing of the maintenance server will be described below.

<Configuration of maintenance server>
FIG. 8 is a functional block diagram illustrating an example of the maintenance server according to the first embodiment. The maintenance server 40 shown in FIG. 8 includes a communication unit 11, a table update unit 41, a temporary table storage unit 42, a maintenance table storage unit 13, and a command issue unit 14 connected to the network 30.

  The table update unit 41 updates the temporary table stored in the temporary table storage unit 42 and the maintenance table stored in the maintenance table storage unit 13 based on the terminal information input from the communication unit 11. The temporary table has the same items as the maintenance table.

<Remote maintenance system operation>
FIG. 9 is a diagram for explaining the operation of the remote maintenance system according to the second embodiment. In FIG. 9, the update status of the temporary table and the maintenance table is shown in time series. In the temporary table and the maintenance table in FIG. 9, only the terminal ID is shown among the items for the sake of brevity. Further, the temporary table and the maintenance table have items other than the “operation flag” among the items shown in FIG. 5. That is, in this embodiment, the “operation flag” is not necessary. ATM1 corresponds to the ATM terminal 20-1, ATM2 corresponds to the ATM terminal 20-2, and ATM3 corresponds to the ATM terminal 20-3. Each time in FIG. 9 is displayed for 24 hours.

  At 16:00 on March 1, ATM1, ATM2, and ATM3 were newly established. ATM1 and ATM2 are installed in a bank store, and the operating hours of ATM1 and ATM2 are from 8:00 to 22:00. For this reason, the power supply of ATM1 and ATM2 is set to be automatically turned on at 8 o'clock every day and automatically turned off at 22 o'clock every day. On the other hand, ATM3 is installed in a 24-hour convenience store and is a 24-hour ATM. For this reason, ATM3 is set to restart at 2 o'clock every day.

  The ATM 3 that is turned on at 2:00 on March 2 transmits its terminal information to the maintenance server 40 when communication with the maintenance server 40 is established after startup. In the maintenance server 40 that has received the ATM3 terminal information, the table update unit 41 registers the ATM3 terminal information in the temporary table.

  The ATMs 1 and 2 that are turned on at 8 o'clock on March 2 transmit terminal information of their own terminals to the maintenance server 40 when communication with the maintenance server 40 is established after startup. In the maintenance server 40 that has received the ATM1 and ATM2 terminal information, the table updating unit 41 adds the ATM1 terminal information and the ATM2 terminal information to the temporary table.

  The table update unit 41 fully updates the maintenance table stored in the maintenance table storage unit 13 with the temporary table stored in the temporary table storage unit 42 at 10 o'clock every day. Accordingly, at 10 o'clock on March 2, the table updating unit 41 fully updates the maintenance table with the temporary table in which the terminal information of ATM1, ATM2, and ATM3 is registered. After all the updates, the table update unit 41 clears the temporary table.

  At 22:00 on March 2, ATM1 and ATM2 are turned off.

  The ATM 3 restarted at 2 o'clock on March 3 transmits terminal information of its own terminal to the maintenance server 40 when communication with the maintenance server 40 is established after startup. In the maintenance server 40 that has received the ATM3 terminal information, the table update unit 41 registers the ATM3 terminal information in the temporary table.

  Here, the start time of ATM 2 on March 3 was changed from 8 o'clock to 14:00 due to the occurrence of a special schedule.

  Therefore, at 8 o'clock on March 3, only the power source of ATM1 of ATM1 and ATM2 is turned on. The ATM 1 that is turned on transmits terminal information of its own terminal to the maintenance server 40 when communication with the maintenance server 40 is established after startup. In the maintenance server 40 that has received the ATM1 terminal information, the table update unit 41 adds the ATM1 terminal information to the temporary table.

  Therefore, at 10:00 on March 3, ATM1 terminal information and ATM3 terminal information exist in the temporary table, but ATM2 terminal information does not exist. Therefore, the table updating unit 41 fully updates the maintenance table with the temporary table in which the terminal information of ATM1 and ATM3 is registered at 10:00 on March 3. After all the updates, the table update unit 41 clears the temporary table.

  At 2 o'clock on March 3, ATM2 is turned on. The ATM 2 that is turned on transmits the terminal information of its own terminal to the maintenance server 40 when communication with the maintenance server 40 is established after startup. In the maintenance server 40 that has received the ATM2 terminal information, the table update unit 41 checks whether the ATM2 terminal information exists in the maintenance table. Here, since the ATM2 terminal information does not exist in the maintenance table, the table update unit 41 adds the ATM2 terminal information to the maintenance table.

  At 22:00 on March 3, ATM1 and ATM2 are turned off.

  The ATM 3 restarted at 2 o'clock on March 4 transmits terminal information of its own terminal to the maintenance server 40 when communication with the maintenance server 40 is established after startup. In the maintenance server 40 that has received the ATM3 terminal information, the table update unit 41 registers the ATM3 terminal information in the temporary table.

  At 8 o'clock on March 4, ATM1 and ATM2 are turned on. The ATM 1 and ATM 2 that are turned on transmit terminal information of their own terminals to the maintenance server 40 when communication with the maintenance server 40 is established after activation. In the maintenance server 40 that has received the ATM1 and ATM2 terminal information, the table updating unit 41 adds the ATM1 terminal information and the ATM2 terminal information to the temporary table.

  Therefore, at 10:00 on March 4, each terminal information of ATM1, ATM2, and ATM3 exists in the temporary table. The table updating unit 41 fully updates the maintenance table with a temporary table in which terminal information of ATM1, ATM2, and ATM3 is registered at 10:00 on March 4. After all the updates, the table update unit 41 clears the temporary storage table.

  Therefore, as in the first embodiment, from 10:00 on March 2 to 10:00 on March 3, the maintenance table includes ATM1, ATM2, and ATM3 that are operating at 10:00 on March 2. , ATM1, ATM2, and ATM3 are targets of remote maintenance. Also, from 10:00 on March 3 to 14:00 on March 3, ATM1 and ATM3 operating at 10:00 on March 3 are included in the maintenance table, so ATM1 and ATM3 are subject to remote maintenance. It becomes. Since ATM2 is added to the maintenance table at 13:00 on March 3, ATM1, ATM2, and ATM3 are targeted for remote maintenance from 14:00 on March 3 to 10:00 on March 4.

<Maintenance server processing>
FIG. 10 is a flowchart for explaining the processing of the maintenance server according to the second embodiment. The flowchart shown in FIG. 10 starts when the power of the maintenance server 40 is turned on and ends when the power is turned off.

  The table updating unit 41 determines whether or not the current time is on-time (step S01). If the current time is not on time (step S01: No), the process proceeds to step S05.

  When the current time is on-time (step S01: Yes), the table update unit 41 fully updates the maintenance table stored in the maintenance table storage unit 13 with the temporary table stored in the temporary table storage unit 42. Then, after all the updates, the temporary table is cleared (step S71).

  Next, the table updating unit 41 determines whether terminal information has been received, that is, whether terminal information has been input from the communication unit 11 (step S05). When the terminal information is not received (step S05: No), the process returns to step S01.

  When the terminal information is received (step S05: Yes), the table updating unit 41 determines whether or not the terminal ID of the received terminal information exists in the maintenance table (step S06).

  When the terminal ID of the received terminal information exists in the maintenance table (step S06: Yes), the table update unit 41 adds the terminal information to the temporary table (step S72). After the terminal information is added to the temporary table, the process returns to step S01.

  When the terminal ID of the received terminal information does not exist in the maintenance table (step S06: No), the table update unit 41 adds the terminal information to the maintenance table (step S08). After the terminal information is added to the maintenance table, the process returns to step S01.

  In the above, each Example of Example 1, 2 was demonstrated.

  As described above, in each of the above embodiments, information on the ATM terminal 20 that is the object of remote maintenance is registered in the maintenance table. The table updating units 12 and 41 update the maintenance table every day (for example, every day at 10 o'clock) based on information transmitted from the ATM terminal 20 when the ATM terminal 20 is started up, and the ATM terminal operating on time While 20 is included in the maintenance table as a remote maintenance target, the ATM terminal 20 that is not operating on time is not included in the maintenance table.

  By doing so, the maintenance servers 10 and 40 automatically collect terminal information from each ATM terminal 20 and update the maintenance table when each ATM terminal 20 is activated, thereby reducing the work burden on the maintenance worker. At the same time, terminal information registration and deletion mistakes can be prevented.

  In each of the above embodiments, when the ATM terminal 20 that is not operating on time is started after the fixed time, the table updating units 12 and 41 set the ATM terminal 20 as a remote maintenance target at the time of starting. Include in

  By doing so, the ATM terminal 20 subject to remote maintenance can be added to the maintenance table even at a time other than the scheduled time, so that omission of registration in the maintenance table can be prevented.

[Other embodiments]
[1] The maintenance servers 10 and 40 can be realized by the following hardware configuration, for example. FIG. 11 is a diagram illustrating a hardware configuration example of the maintenance server. As shown in FIG. 11, the maintenance servers 10 and 40 include a processor 10a, a memory 10b, and a network interface module 10c as hardware components. Examples of the processor 10a include a CPU (Central Processing Unit), a DSP (Digital Signal Processor), and an FPGA (Field Programmable Gate Array). The maintenance server 10 may have an LSI (Large Scale Integrated circuit) including a processor 10a and peripheral circuits. Examples of the memory 10b include a RAM (Random Access Memory) such as an SDRAM (Synchronous Dynamic Random Access Memory), a ROM (Read Only Memory), a flash memory, and the like. The communication unit 11 is realized by the network interface module 10c. The table updating units 12 and 41 and the command issuing unit 14 are realized by the processor 10a. The maintenance table storage unit 13 and the temporary table storage unit 42 are realized by the memory 10b.

  And each process in the said description in the maintenance servers 10 and 40 may be implement | achieved by making the processor 10a run the program corresponding to each process. For example, a program corresponding to each process in the above description may be stored in a storage unit such as the memory 10b or an HDD (Hard Disk Drive), and the program may be read from the storage unit and executed by the processor 10a.

  [2] The ATM terminal 20 can be realized by the following hardware configuration, for example. FIG. 12 is a diagram illustrating a hardware configuration example of the ATM terminal. As shown in FIG. 12, the ATM terminal 20 includes a processor 20a, a memory 20b, a deposit / withdrawal mechanism 20c, and a network interface module 20d as hardware components. Examples of the processor 20a include a CPU, DSP, FPGA, and the like. The ATM terminal 20 may have an LSI including a processor 20a and peripheral circuits. Examples of the memory 20b include RAM such as SDRAM, ROM, flash memory, and the like. The communication unit 23 is realized by the network interface module 20d. The terminal information acquisition unit 22 and the maintenance execution unit 24 are realized by the processor 20a. The terminal information storage unit 21 is realized by the memory 20b.

  And each process in the said description in the ATM terminal 20 may be implement | achieved by making the processor 20a run the program corresponding to each process. For example, a program corresponding to each process in the above description may be stored in the memory 20b, and the program may be read from the memory 20b by the processor 20a and executed.

DESCRIPTION OF SYMBOLS 1 Remote maintenance system 10 Maintenance server 20-1-20-3 ATM terminal 30 Network 11, 23 Communication part 12, 41 Table update part 13 Maintenance table storage part 14 Command issue part 42 Temporary table storage part 21 Terminal information storage part 22 Terminal Information acquisition unit 24 Maintenance execution unit

Claims (4)

A table in which information for remote maintenance of the target der Ru end terminal device is registered,
Each of the plurality of terminal devices is registered in the table in association with the first state and the second state of the flag, and the state of the flag of each terminal device is confirmed every day, and the flag is in the first state. After deleting the terminal device from the table, the flag of the terminal device remaining in the table is changed from the second state to the first state, and based on the information transmitted from the terminal device, the transmission source of the information It is determined whether or not the terminal device exists in the table. When the terminal device that is the transmission source of the information exists in the table, the flag of the terminal device is updated to the second state, and the transmission of the information is performed. When the original terminal device does not exist in the table, the terminal device is added to the table, the flag of the terminal device is set to the second state, and the terminal device registered in the table An update unit to be subjected to remote maintenance,
A maintenance server. The updating unit, when the scheduled terminal device that is not running on is started in the later scheduled and adds the terminal device before Symbol table at that start time,
The maintenance server according to claim 1. And registered in association with each of the plurality of terminal devices in a first state and a second state of the flag in the table information of the target der Ru end terminal device for remote maintenance is registered,
After checking the state of the flag of each terminal device on a daily basis and deleting the terminal device in which the flag is in the first state from the table, the flag of the terminal device remaining in the table is changed from the second state to the first state. Change to one state,
Based on the information transmitted from the terminal device, it is determined whether or not the terminal device that is the transmission source of the information exists in the table, and when the terminal device that is the transmission source of the information exists in the table, When the terminal device flag is updated to the second state, and the terminal device that is the transmission source of the information does not exist in the table, the terminal device flag is added to the table and then the terminal device flag is set to the second state. Set to the state,
The terminal device registered in the table is the target of remote maintenance,
A table update program that causes the maintenance server to execute processing. And registered in association with each of the plurality of terminal devices in a first state and a second state of the flag in the table information of the target der Ru end terminal device for remote maintenance is registered,
After checking the state of the flag of each terminal device on a daily basis and deleting the terminal device in which the flag is in the first state from the table, the flag of the terminal device remaining in the table is changed from the second state to the first state. Change to one state,
Based on the information transmitted from the terminal device, it is determined whether or not the terminal device that is the transmission source of the information exists in the table, and when the terminal device that is the transmission source of the information exists in the table, When the terminal device flag is updated to the second state, and the terminal device that is the transmission source of the information does not exist in the table, the terminal device flag is added to the table and then the terminal device flag is set to the second state. Set to the state,
The terminal device registered in the table is the target of remote maintenance,
Table update method.

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