JP2021002150A - Transmission device - Google Patents

Abstract

To prevent increasing an area occupied by a substrate mounted in a transmission device and taking a long time for updating the study of a circuit design in the transmission device or its software program.SOLUTION: The transmission device is used in a transmission system that relays wireless communications between a wireless base station and a mobile terminal. The transmission device has a storage unit, an FPGA, a temporary storage unit, and a processor. The storage unit stores a software program. The FPGA receives from another transmission device in the transmission system a split file, which is a split update file used to update the software program. The temporary storage unit stores the split file. The processor writes the split file received by the FPGA in the temporary storage unit and also writes in the storage unit the split file stored in the temporary storage unit.SELECTED DRAWING: Figure 1

Description

An embodiment of the present invention relates to a transmission device.

A transmission system such as an optical repeater system connected to a monitoring control device is composed of various transmission devices such as a master unit, a repeater, and a slave unit.

Japanese Unexamined Patent Publication No. 2016-46776

By the way, a function of updating a software program stored in a transmission device of a transmission system via an optical fiber is being developed. On the other hand, the amount of data of software programs executed in transmission devices is increasing due to the support for new frequency bands used for wireless communication and the expansion of frequency bands used for wireless communication. Therefore, in the transmission system, as the amount of data of the software program executed in the transmission device increases, it becomes necessary to prepare a temporary storage unit used for updating the software program, and the capacity of the temporary storage unit increases. There is. As a result, the area occupied by the board mounted on the transmission device increases, and it takes time to study the circuit design in the transmission device and update the software program.

The transmission device of the embodiment is used in a transmission system that relays wireless communication between a wireless base station and a mobile terminal. The transmission device includes a storage unit, an FPGA, a temporary storage unit, and a processor. The storage unit stores the software program. The FPGA receives a divided file obtained by dividing the update file used for updating the software program from another transmission device of the transmission system. The temporary storage unit stores the divided file. The processor writes the divided file received by the FPGA to the temporary storage unit, and writes the divided file stored in the temporary storage unit to the storage unit.

FIG. 1 is a diagram showing an example of a schematic configuration of an optical repeater system to which a transmission system including the transmission device according to the present embodiment is applied. FIG. 2 is a block diagram showing an example of the hardware configuration of the master unit included in the optical repeater system according to the present embodiment. FIG. 3 is a block diagram showing an example of the hardware configuration of the repeater included in the optical repeater system according to the present embodiment. FIG. 4 is a block diagram showing an example of the hardware configuration of the slave unit included in the optical repeater system according to the present embodiment. FIG. 5 is a sequence diagram showing an example of a flow of transmission / reception processing of an update file by the master unit of the optical repeater system according to the present embodiment. FIG. 6 is a sequence diagram showing an example of a flow of transmission / reception processing of an update file by a repeater or a slave unit of the optical repeater system according to the present embodiment.

Hereinafter, an example of an optical repeater system to which a transmission system including the transmission device according to the present embodiment is applied will be described with reference to the accompanying drawings.

FIG. 1 is a diagram showing an example of a schematic configuration of an optical repeater system to which a transmission system including the transmission device according to the present embodiment is applied. First, an example of an optical repeater system to which the transmission system according to the present embodiment is applied will be described with reference to FIG.

As shown in FIG. 1, the optical repeater system according to the present embodiment includes a radio base station BS, a master unit MU, a repeater HU, a slave unit RU, and a monitoring control device 1.

In the present embodiment, the master unit MU, the repeater HU, and the slave unit RU are a plurality of optical transmission devices connected to each other via an optical fiber OF. Then, the master unit MU, the repeater HU, and the slave unit RU relay the wireless communication between the wireless base station BS and the mobile terminal (for example, a smartphone or tablet terminal) via the optical fiber OF.

That is, in the master unit MU, the repeater HU, and the slave unit RU, the wireless communication signal (radio wave) from the wireless base station BS does not reach (or is difficult to reach) directly, that is, in a building or an underground mall, which is a so-called dead zone. , A repeater device that enables mobile terminals to be used in subway premises, tunnels, etc. In the present embodiment, as an example of a transmission device used in a transmission system that relays wireless communication between a wireless base station BS and a mobile terminal, an example in which an optical transmission device connected via an optical fiber OF is used. As described above, any transmission device that can relay wireless communication between the wireless base station BS and the mobile terminal may be a transmission device that is connected via a communication path other than the optical fiber OF.

The wireless base station BS is a wireless base station installed outdoors or the like that can receive radio waves for wireless communication.

The master unit MU is connected to the radio base station BS via a coaxial cable, and is connected to the repeater HU and the slave unit RU via the optical fiber OF. Further, the master unit MU is connected to the monitoring control device 1 via the network NT.

The repeater HU is connected to the master unit MU and the slave unit RU via the optical fiber OF.

The slave unit RU is connected to the master unit MU, the repeater HU, and another slave unit RU via the optical fiber OF. Further, the slave unit RU is provided with an antenna 405 for wireless communication with the mobile terminal. The slave unit RU includes an antenna 405 for wireless communication with the mobile terminal.

The monitoring control device 1 is a PC (Personal Computer) or the like, and monitors the entire optical repeater system. Then, the monitoring control device 1 stores the monitoring results of the entire optical repeater system, and displays the monitoring results on a display unit (not shown) in response to a request from the operator. As a result, the monitoring control device 1 notifies the operator of the monitoring result of the entire optical repeater system and the like.

Further, the monitoring control device 1 generates a file (hereinafter referred to as an update file) used for updating a software program executed in an optical transmission device such as a master unit MU, a repeater HU, and a slave unit RU. Then, the monitoring control device 1 divides the generated update file into a plurality of files (hereinafter referred to as divided files), and transmits the divided files to the master unit MU via the network NT.

In the present embodiment, the divided file includes the length of the divided file, the checksum of the divided file, and the identifier of the update file including the divided file (hereinafter, referred to as a file identifier, for example, version information). It has been added.

Further, in the present embodiment, the device identifier is added to the divided file in addition to the length of the divided file, the checksum, and the program identifier. Here, the device identifier is an identifier of the optical transmission device that updates the software program by the divided file. For example, the monitoring control device 1 adds an identifier of an optical transmission device that updates a software program, which is input by an operator via an input unit (not shown), to the divided file as a device identifier.

Next, an example of the hardware configuration of the master unit MU included in the optical repeater system according to the present embodiment will be described with reference to FIG. FIG. 2 is a block diagram showing an example of the hardware configuration of the master unit included in the optical repeater system according to the present embodiment.

As shown in FIG. 2, the master unit MU according to the present embodiment has a CPU 201, a RAM 202, a ROM 203, and an FPGA 204.

The RAM (Random Access Memory) 202 is an example of a temporary storage unit that temporarily stores various information such as a divided file received from the monitoring control device 1. Further, the RAM 202 functions as a work area when the CPU 101, which will be described later, executes a software program.

The ROM (Read Only Memory) 203 is an example of a non-volatile storage unit (storage unit) that stores various information such as a divided file received from the monitoring control device 1 and a software program executed in the optical transmission device.

In the present embodiment, the ROM 203 has a storage area of an active system and a storage area of a standby system. Here, the storage area of the operating system is a storage area for storing the software program executed in the master unit MU. The standby system storage area is a storage area for storing software programs for updating.

In the present embodiment, the ROM 203 is used as the non-volatile storage unit for storing the software program executed in the optical transmission device, but the non-volatile storage unit is not limited to this, for example, the HDD. (Hard Disk Drive), SSD (Solid State Drive), or the like may be used.

The CPU (Central Processing Unit) 201 is an example of a processor, and uses the RAM 202 as a work area to execute a software program stored in the ROM 203 to control the entire master unit MU.

Specifically, the CPU 201 receives the divided file from the external monitoring control device 1 via the network NT, and writes the received divided file to the RAM 202. Next, the CPU 201 reads the divided file from the RAM 202, and writes the read divided file into the ROM 203.

As a result, even if the amount of data in the update file increases due to the support for a new frequency band used for wireless communication and the increase in the capacity of the FPGA 204 due to the expansion of the frequency band used for wireless communication, the update file It is not necessary to increase the capacity of the RAM 202 according to the total amount of data. As a result, it is possible to prevent an increase in the area occupied by the board mounted on the master unit MU, an examination of the circuit design in the master unit MU, and a long time for updating the software program.

Further, the CPU 201 determines whether or not the divided file is normal based on the length, checksum, file identifier, and the like of the divided file added to the divided file stored in the RAM 202. Then, when it is determined that the divided file stored in the RAM 202 is not normal, the CPU 201 does not have to write the divided file stored in the RAM 202 to the ROM 203.

Further, when it is determined that the divided file stored in the RAM 202 is not normal, the CPU 201 tells the monitoring control device 1 via the network NT or the like that the divided file is not normal, and the monitoring result of the entire optical repeater system. Notify as.

The monitoring control device 1 writes that the divided file is not normal as a monitoring result in a storage unit (not shown), and in response to a request from the operator, sends the monitoring result stored in the storage unit (not shown) to the display unit (not shown). To display. As a result, the operator of the monitoring control device 1 can execute processing such as retransmission of the divided file. At that time, the monitoring control device 1 shall repeat the retransmission process of the divided file a preset number of times.

In the present embodiment, the CPU 201 determines whether or not the divided file stored in the RAM 202 is normal, and if it determines that the divided file stored in the RAM 202 is not normal, the CPU 201 does not write the divided file to the ROM 203. In addition, the divided file is deleted from the RAM 202, but the present invention is not limited to this. For example, the CPU 201 may write the divided file to the ROM 203 regardless of whether the divided file stored in the RAM 202 is normal or not.

Further, after storing the divided file in the ROM 203, the CPU 201 reads the divided file from the ROM 203 and transfers the read divided file to the FPGA 204. As a result, the CPU 201 instructs the FPGA 204, which will be described later, to transmit the update file to the repeater HU and the slave unit RU connected by the optical fiber OF.

Further, the CPU 201 determines whether or not the divided file is a divided file used for updating the software program of the master unit MU itself, based on the file identifier added to the divided file stored in the ROM 203. Then, when the CPU 201 determines that the divided file is not the divided file used for updating the software program of the master unit MU itself, the CPU 201 does not update the software program of the master unit MU itself. In that case, the CPU 201 may delete the divided file from the ROM 203 after the divided file is transmitted to the repeater HU or the slave unit RU by the FPGA 204.

On the other hand, when the CPU 201 determines that the divided file is a divided file used for updating the software program of the master unit MU itself, the CPU 201 uses the update file including the divided file to use the software program of the master unit MU itself. Perform the update.

When the ROM 203 has the storage area of the active system and the storage area of the standby system, the CPU 201 updates the software program stored in the storage area of the standby system by using the update file. Then, after the update, the CPU 201 changes the storage area of the standby system to the storage area of the new operating system, and changes the storage area of the operating system before the change to the storage area of the new standby system.

As a result, the software program executed in the master unit MU can be updated even while the software program stored in the storage area of the operating system is being executed. As a result, the system failure time required for updating the software program executed in the optical transmission device can be shortened.

However, if the software program stored in the storage area of the new operating system cannot be normally executed (started), the CPU 201 returns the storage area of the new operating system to the storage area of the standby system and renews it. The storage area of the standby system shall be returned to the storage area of the active system.

Further, when the update file stored in the ROM 203 is loaded due to the transfer of the update file to the FPGA 204, the update of the software program, or the like, the CPU 201 is divided into a plurality of divisions included in the update file stored in the ROM 203. Determine if all the file identifiers added to the file match.

Then, when the file identifiers added to all the divided files included in the update file stored in the ROM 203 match, the CPU 201 loads the divided file stored in the ROM 203. On the other hand, the CPU 201 does not load the divided file stored in the ROM 203 if the file identifiers added to all the divided files included in the update file stored in the ROM 203 do not match.

As a result, when the update file contains an abnormality such as a divided file having a different version, it is possible to prevent the software program from being updated by the update file having the abnormality. As a result, it is possible to prevent the occurrence of a defect in the optical transmission device due to the update of the software program.

Further, the CPU 201 determines that the divided file is not a divided file used for updating the software program of the master unit MU itself, even though the device identifier added to the divided file indicates the master unit MU itself. When the update of the software program of the master unit MU itself is not executed, the monitoring control device 1 is notified via the network NT or the like that the software program of the master unit MU has not been updated.

The monitoring control device 1 writes that the software program of the master unit MU has not been updated in a storage unit (not shown) as a monitoring result of the entire optical repeater system, and stores it in a storage unit (not shown) in response to a request from the operator. The monitoring result to be performed is displayed on a display unit (not shown). As a result, the operator of the monitoring control device 1 can execute processing such as retransmission of the divided file.

The FPGA (Field-Programmable Gate Array) 204 relays wireless communication between the wireless base station BS and the mobile terminal via the optical fiber OF. For example, the FPGA 204 executes various signal processing such as A / D conversion processing on the wireless communication signal input from the wireless base station BS via the coaxial cable, and the wireless communication signal that executes the signal processing. Is transmitted to the repeater HU and the slave unit RU via the optical fiber OF. As a result, the FPGA 204 relays the wireless communication between the wireless base station BS and the mobile terminal.

Further, the FPGA 204 has a repeater HU and a repeater HU in which the divided file input from the CPU 201 is connected to another optical transmission device (in the communication path, lower side (downstream side) than the master unit MU itself) via the optical fiber OF. Send to the slave unit RU). That is, the FPGA 204 transmits the update file read from the ROM 203 by the CPU 201 to the repeater HU and the slave unit RU via the optical fiber OF for each divided file.

In the present embodiment, the monitoring control device 1 divides the update file into a plurality of divided files and transmits the divided files to the master unit MU, but the storage capacity of the RAM 202 of the master unit MU is sufficient. If there is, the update file may be transmitted from the monitoring control device 1 to the master unit MU without dividing the update file into a plurality of divided files in the monitoring control device 1.

In that case, when the CPU 201 transmits the update file stored in the ROM 203 to the repeater HU, the slave unit RU, or the like via the optical fiber OF, the CPU 201 divides the update file stored in the ROM 203 into a plurality of divided files. It is divided and each of the divided files is passed to FPGA 204. Then, the FPGA 204 transmits the divided file input from the CPU 201 to the repeater HU and the slave unit RU via the optical fiber OF.

Next, an example of the hardware configuration of the repeater HU included in the optical repeater system according to the present embodiment will be described with reference to FIG. FIG. 3 is a block diagram showing an example of the hardware configuration of the repeater included in the optical repeater system according to the present embodiment. In the following description, description of the same configuration as the master unit MU will be omitted.

As shown in FIG. 3, the repeater HU according to the present embodiment also has a CPU 301, a RAM 302, a ROM 303, and an FPGA 304, similarly to the master unit MU.

The RAM 302 is an example of a temporary storage unit that temporarily stores various information such as a divided file received from the master unit HU or another repeater HU. Further, the RAM 302 functions as a work area when the CPU 301, which will be described later, executes a software program.

The ROM 303 is an example of a non-volatile storage unit (storage unit) that stores various information such as a divided file received from the master unit HU or another repeater HU and a software program executed by the CPU 301 described later.

The CPU 301 is an example of a processor, and uses the RAM 302 as a work area to execute a software program stored in the ROM 303 to control the entire repeater HU.

Further, the CPU 301 executes various processes such as writing the divided file to the RAM 302 and the ROM 303 and reading the divided file from the ROM 303, similarly to the CPU 201 of the master unit MU.

As a result, even if the amount of data in the update file increases due to the increase in the capacity of the FPGA 304 due to the support for the new frequency band used for wireless communication and the expansion of the frequency band used for wireless communication, the entire update file It is not necessary to increase the capacity of the RAM 302 according to the amount of data. As a result, it is possible to prevent an increase in the area occupied by the board mounted on the repeater HU, an examination of the circuit design in the repeater HU, and a long time for updating the software program.

However, unlike the master unit MU, the CPU 301 of the repeater HU is connected to another optical transmission device (in the communication path, the master unit MU or the like connected to the higher side (upstream side) of the repeater HU itself) by the FPGA 304 described later. It is assumed that the divided file received from the repeater HU) is written to the RAM 302 and the ROM 303.

The FPGA 304 relays the communication between the radio base station BS and the mobile terminal via the optical fiber OF. Further, the FPGA 304 receives the divided file from the master unit MU or another repeater HU via the optical fiber OF. Further, the FPGA 304 transfers the update file read from the ROM 303 by the CPU 301 to another optical transmission device (in the communication path, lower side (downstream side) than the repeater HU itself) for each divided file via the optical fiber OF. It is transmitted to other connected repeater HU and slave unit RU).

Next, an example of the hardware configuration of the slave unit RU included in the optical repeater system according to the present embodiment will be described with reference to FIG. FIG. 4 is a block diagram showing an example of the hardware configuration of the slave unit included in the optical repeater system according to the present embodiment. In the following description, description of the same configuration as the master unit MU will be omitted.

As shown in FIG. 4, the slave unit RU according to the present embodiment also has a CPU 401, a RAM 402, a ROM 403, an FPGA 404, and an antenna 405, similarly to the master unit MU.

The antenna 405 is an antenna that emits radio waves and enables wireless communication with a mobile terminal.

The RAM 402 is an example of a temporary storage unit that temporarily stores various information such as a divided file received from the master unit HU, the repeater HU, or another slave unit RU. Further, the RAM 402 functions as a work area when the CPU 401, which will be described later, executes a software program.

The ROM 403 is an example of a non-volatile storage unit (storage unit) that stores various information such as a divided file received from the master unit HU, the repeater HU, or another slave unit RU, and a software program executed by the CPU 401 described later. is there.

The CPU 401 is an example of a processor, and uses the RAM 402 as a work area to execute a software program stored in the ROM 403 to control the entire slave unit RU.

Further, the CPU 401 executes various processes such as storing the divided file in the RAM 402 and the ROM 403 and reading the divided file from the ROM 403, similarly to the CPU 201 of the master unit MU.

As a result, even if the amount of data in the update file increases due to the increase in the capacity of the FPGA 404 due to the support for the new frequency band used for wireless communication and the expansion of the frequency band used for wireless communication, the entire update file It is not necessary to increase the capacity of the RAM 402 according to the amount of data. As a result, it is possible to prevent an increase in the area occupied by the board mounted on the slave unit RU, an examination of the circuit design in the slave unit RU, and a long time for updating the software program.

However, unlike the master unit MU, the CPU 301 of the repeater HU is a master unit MU connected to another optical transmission device (in the communication path, higher side (upstream side) than the slave unit RU itself) by the FPGA 404 described later. It is assumed that the divided file received from the repeater HU and the other slave unit RU) is written to the RAM 402 and the ROM 403.

The FPGA 404 relays the communication between the radio base station BS and the mobile terminal located in the range where wireless communication is possible by using the antenna 405 via the optical fiber OF. Further, the FPGA 404 receives the divided file from the master unit MU, the repeater HU, or another slave unit RU via the optical fiber OF. Further, the FPGA 404 is a slave unit RU in which the divided file read from the ROM 403 by the CPU 401 is connected to another optical transmission device (in the communication path, lower side (downstream side) than the slave unit RU itself) via the optical fiber OF. ).

Next, an example of the flow of the transmission / reception processing of the update file by the master unit MU of the optical repeater system according to the present embodiment will be described with reference to FIG. FIG. 5 is a sequence diagram showing an example of a flow of transmission / reception processing of an update file by the master unit of the optical repeater system according to the present embodiment.

When the monitoring control device 1 generates the update file, the monitoring control device 1 divides the update file into N divided files (where N is an integer of 2 or more) (step S501). Next, the monitoring control device 1 transmits the update file to the master unit MU for each divided file via the network NT (step S502). The monitoring control device 1 repeats transmission of the divided files to the master unit MU by the number of divided files (N) obtained by dividing the update file.

When the CPU 201 of the master unit MU receives the divided file from the monitoring control device 1 via the network NT, the CPU 201 writes the divided file to the RAM 202 (step S503). Next, the CPU 201 determines whether or not the divided file written in the RAM 202 is normal (step S504).

Further, the CPU 201 reads the divided file from the RAM 202 (step S505) and stores the read divided file in the ROM 203 (step S506). However, if it is determined in step S504 that the divided file is not normal, the CPU 201 does not write the divided file stored in the RAM 202 to the ROM 203.

The CPU 201 repeats the processes shown in steps S503 to S506 for the number of divided files (N) obtained by dividing the update file.

When the divided file is written to the ROM 203, the CPU 201 reads the divided file from the ROM 203 and transfers the read divided file to the FPGA 204. The FPGA 204 transmits the divided file input from the CPU 201 to the repeater HU or the slave unit RU connected via the optical fiber OF.

Next, an example of a flow of transmission / reception processing of an update file by the repeater HU or the slave unit RU of the optical repeater system according to the present embodiment will be described with reference to FIG. FIG. 6 is a sequence diagram showing an example of a flow of transmission / reception processing of an update file by a repeater or a slave unit of the optical repeater system according to the present embodiment. In the following description, the transmission / reception processing of the update file in the repeater HU will be described, but the transmission / reception processing of the update file is also performed in the slave unit RU in the same manner.

The FPGA 204 of the master unit MU transmits the divided file input from the CPU 201 to the repeater HU via the optical fiber OF (step S601). The FPGA 204 repeats transmission of the divided files to the repeater HU by the number of divided files (N) obtained by dividing the update file.

When the CPU 301 of the repeater HU receives the divided file from the master unit MU via the optical fiber OF, the CPU 301 writes the received divided file to the RAM 302 (step S602). Next, the CPU 301 determines whether or not the divided file written in the RAM 302 is normal (step S603).

Further, the CPU 301 reads the divided file from the RAM 302 (step S604) and writes the read divided file to the ROM 303 (step S605). However, if it is determined in step S603 that the divided file is not normal, the CPU 301 does not write the divided file stored in the RAM 302 to the ROM 303.

The CPU 301 repeats the processes shown in steps S602 to S605 for the number of divided files (N) obtained by dividing the update file.

When the divided file is written to the ROM 303, the CPU 301 reads the divided file from the ROM 303 and transfers the read divided file to the FPGA 304. The FPGA 304 transmits the divided file input from the CPU 301 to the repeater HU or the slave unit RU connected via the optical fiber OF.

As described above, according to the optical repeater system according to the present embodiment, the capacity of FPGAs 204, 304, and 404 is increased by supporting a new frequency band used for wireless communication and expanding the frequency band used for wireless communication. Even if the amount of data in the update file increases, it is not necessary to increase the capacity of the RAMs 202, 302, and 402 according to the amount of data in the entire update file. As a result, the area occupied by the board mounted on the master unit MU, the repeater HU, and the slave unit RU increases, and the circuit design in the master unit MU, the repeater HU, and the slave unit RU is examined and the software program is updated. It is possible to prevent a long period of time.

Although embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. This novel embodiment can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1 Monitoring and control device 201, 301, 401 CPU
202, 302, 402 RAM
203, 303, 403 ROM
204, 304, 404 FPGA
405 Antenna BS wireless base station MU master unit HU repeater RU slave unit NT network OF optical fiber

Claims (8)

A transmission device used in a transmission system that relays wireless communication between a wireless base station and a mobile terminal.
A storage unit that stores software programs
An FPGA that receives a divided file obtained by dividing an update file used for updating the software program from another transmission device of the transmission system.
A temporary storage unit that stores the divided file and
A processor that writes the divided file received by the FPGA to the temporary storage unit and writes the divided file stored in the temporary storage unit to the storage unit.
A transmission device comprising. The processor reads the divided file from the storage unit and reads the divided file.
The transmission device according to claim 1, wherein the FPGA transmits the divided file read by the processor to the other transmission device. The transmission device according to claim 1 or 2, wherein the length of the divided file, the checksum of the divided file, and the file identifier of the update file are added to the divided file. The processor determines whether or not the divided file stored in the temporary storage unit is normal, and if it determines that the divided file is not normal, the processor does not write the divided file to the storage unit. The transmission device according to any one of 3 to 3. The processor is requested to load the update file stored in the storage unit when all the file identifiers added to the divided files included in the update file stored in the storage unit match. Item 3. The transmission device according to item 3. The storage unit further has a storage area of an operating system that stores the software program executed in the transmission device, and a storage area of a standby system that stores the software program for updating.
A claim in which the processor updates the software program stored in the storage area of the standby system by using the update file, and after the update, changes the storage area of the standby system to the storage area of the operating system. The transmission device according to any one of 1 to 5. The processor determines whether or not the divided file is the divided file used for updating the software program of the transmission device itself, based on the file identifier added to the divided file stored in the storage unit. When it is determined that the divided file is not the divided file used for updating the software program of the transmission device itself, the divided file is transmitted from the storage unit after transmitting the divided file to another transmission device. The transmission device according to claim 3 or 5 to be deleted. Further, the device identifier of the transmission device that updates the software program by the split file is added to the split file.
The processor determines that the split file is not the split file used to update the software program of the transmission device itself, even though the device identifier indicates the transmission device itself, and the split file 7. The transmission device according to claim 7, which notifies an external monitoring and control device that the software program has not been updated when the software program is deleted from the storage unit.

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