JP5770546B2 - SIP server, network system, power control method and program for network device - Google Patents

Description

The present invention relates to a SIP (Session Initiation Protocol) server , a network system, a power control method for a network device, and a program.

  In recent years, activities from the viewpoint of ecology such as CO2 reduction and power saving have been activated. Even in the operation of a server that operates for 24 hours, before a long holiday period or a large consecutive holiday period, an operator may turn off the server from the viewpoint of ecology or saving electricity costs. In the case where servers are distributed and arranged in remote locations, in order to perform a power-off operation, the worker needs to move to the installation location of each server.

  Patent Document 1 describes that the information processing apparatus is powered off from a remote location via a communication line.

  Patent Document 2 describes that the power supply of the remote control device is automatically turned off in synchronization with the power supply cut-off of the electric device.

  Japanese Patent Application Laid-Open No. 2004-228561 describes that power control of a processing line of a packet processing device is performed according to the amount of packet traffic.

JP-A-9-212261 JP2007-318336A JP2009-49887A

  By using the technology described in Patent Document 1 and the technology called Wake-on-LAN (registered trademark), the server can be powered off by remote operation via the network. Become. This eliminates the need for the worker to move to the installation location of the server, thereby reducing the burden on the worker.

  However, these technologies have a problem in that it is impossible to prevent erroneous server power-off. For example, if the information for identifying the server (such as an address on the network) input by the operator for powering off is incorrect, the server may be unintentionally powered off. For this reason, it is necessary for the worker to manage information for identifying the server, and the burden on the worker increases.

An object of the present invention is to provide a SIP server , a network system, a network device power supply control method, and a program that solve the above-described problems and reduce the burden on the operator.

The first SIP server according to the present invention is:
The first communication data that is data transmitted from the transmission source to the transmission destination, and the second communication data that is a response to the first communication data transmitted from the transmission destination to the transmission source are transferred. Data transfer processing means;
A power-off information storage processing means for storing the power-off information in a predetermined storage means when the first communication data includes power-off information for instructing power-off;
It is determined whether or not the second communication data is a response of the first communication data, and when it is determined that the response is a response, a power-off processing unit that performs power-off based on the power-off information is provided.

The second SIP server according to the present invention is:
The first communication data that is data transmitted from the transmission source to the transmission destination, and the second communication data that is a response to the first communication data transmitted from the transmission destination to the transmission source are transferred. Data transfer processing means;
When it is determined whether the second communication data is a response to the first communication data, the second communication data is determined to be a response, and the second communication data includes power-off information that instructs power-off. Power-off processing means for performing power-off based on the power-off information.

The network system according to the present invention includes:
Any of the SIP servers described above;
And an information processing apparatus.

A power control method for a network device according to the present invention includes:
A network device that is on the communication path between the source and destination
Transfer the first communication data that is the data sent from the source to the destination,
Transferring the second communication data, which is a response of the first communication data, transmitted from the transmission destination to the transmission source;
It is determined whether or not the second communication data is a response to the first communication data, and when it is determined to be a response and is included in the first communication data or the second communication data, the power-off information Power off the network device itself based on the above.

The program according to the present invention is:
To the computer of the network device intervening on the communication path between the source and destination,
A process of transferring first communication data which is data transmitted from the transmission source to the transmission destination;
A process of transferring second communication data, which is a response to the first communication data, transmitted from the transmission destination to the transmission source;
It is determined whether or not the second communication data is a response to the first communication data, and it is determined that the second communication data is a response, and power-off information that instructs the first communication data or the second communication data to turn off the power Is included, the network device itself is powered off based on the power-off information.

The SIP server , network system, network device power control method and program according to the present invention can reduce the burden on the operator in the power control of the network device.

It is a figure explaining the structure and process outline | summary of a network system which concern on the 1st Embodiment of this invention. It is a figure showing the routing information which the SIP server 11 hold | maintains. It is a figure showing the SIP signal transmitted from the worker terminal 21 by using the worker terminal 22 as a transmission destination. It is a sequence diagram explaining the outline | summary of the processing operation of the network system N1 which concerns on the 1st Embodiment of this invention. It is a block block diagram which shows the main function structures of the SIP server which concerns on the 1st Embodiment of this invention. It is a figure explaining the structure and process outline | summary of the network system which concern on the 2nd Embodiment of this invention. It is a figure showing the routing information which the SIP server 11 hold | maintains. It is a figure showing the SIP signal transmitted from the worker terminal 21 by using the worker terminal 22 as a transmission destination. It is a figure showing the SIP signal transmitted from the worker terminal 21 by using the worker terminal 23 as a transmission destination. It is a sequence diagram explaining the outline | summary of the processing operation of the network system N2 which concerns on the 2nd Embodiment of this invention. It is a block block diagram which shows the main function structures of the network device which concerns on the 3rd Embodiment of this invention. And FIG. 11 is a block diagram illustrating an example of elements constituting a computer.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
FIG. 1 is a diagram for explaining the configuration and processing outline of a network system according to the first embodiment of the present invention. The network system N1 according to the first embodiment of the present invention includes worker terminals 21 and 22 and SIP (Session Initiation Protocol) servers 11 and 12. The worker terminals 21 and 22 are sometimes called information processing apparatuses. The SIP servers 11 and 12 are sometimes called network devices. The number of SIP servers 11 and 12 may be other than two. That is, one unit or three or more units may be used. The SIP servers 11 and 12 may be computers such as server computers or dedicated devices such as router devices. The worker terminals 21 and 22 may be computers.

  The worker terminal 21 and the SIP server 11 are connected to be communicable. Further, the SIP servers 11 and 12, and the SIP server 12 and the worker terminal 22 are similarly connected. The worker terminals 21 and 22 and the SIP servers 11 and 12 hold route information for performing communication between the worker terminal 21 and the worker terminal 22 (route R1).

  The means for connecting the worker terminals 21 and 22 and the SIP servers 11 and 12 may be a LAN (Local Area Network) or a WAN (Wide Area Network) such as the Internet.

  In the worker terminals 21 and 22 and the SIP servers 11 and 12, the SIP protocol capable of specifying “power-off information” by extending the SDP (Session Description Protocol) portion of the SIP protocol is operating. “Power-off information” is information for instructing power-off. When specifying “power-off information”, in the first embodiment, “d = poweroff” is described in the SDP portion of the SIP protocol.

  The SIP servers 11 and 12 have a function of interpreting a parameter “d = poweroff” obtained by extending the SDP portion of the SIP protocol and autonomously powering off the server.

  FIG. 2 is a diagram illustrating route information held by the SIP server 11. The routing information in FIG. 2 indicates that when the transmission destination of the communication data received by the SIP server 11 is the worker terminal 22, the SIP server 11 transfers the communication data to the SIP server 12 that is the next transmission destination. ing.

  FIG. 3 is a diagram illustrating a SIP signal transmitted from the worker terminal 21 with the worker terminal 22 as a transmission destination.

  FIG. 4 is a sequence diagram illustrating an overview of processing operations of the network system N1 according to the first embodiment of the present invention. Hereinafter, the operation check and power-off processing of the SIP server in the network system N1 will be described with reference to FIGS.

  The worker operates the worker terminal 21 to check the operation of the SIP servers (SIP servers 11 and 12) on the route R1, which is a communication route between the worker terminal 21 and the worker terminal 22, and perform power-off processing. Start. That is, it is confirmed that the SIP server on the route R1 operates normally, and then the power is turned off. The normal operation of the SIP server is confirmed by whether or not the parameters included in the SIP signal are normally processed in the SIP server.

  Confirming that the server operates normally before powering off the server is useful for determining the cause when the server does not start up normally at the next power-on.

  First, as shown in FIG. 3, the worker terminal 21 creates a SIP signal in which “d = poweroff” is specified in the SDP portion as a power-off instruction (power-off information). Then, the worker terminal 21 transmits the created SIP signal with the worker terminal 22 as a transmission destination. The SIP signal transmitted from the worker terminal 21 is transmitted to the SIP server 11 based on the route information held by the worker terminal 21 (step S1 in FIG. 4).

  The SIP server 11 that has received the SIP signal from the worker terminal 21 interprets the parameter “d = poweroff” from the SDP information of the received SIP signal (step S2). Then, the SIP server 11 holds the power-off setting by itself. Then, the SIP server 11 interprets the next transmission destination (SIP server 12) from the request information (INVITE worker terminal 22) in the SIP signal of FIG. 3 and the route information of FIG. Then, the SIP server 11 creates a SIP signal specifying “d = poweroff” in the SDP portion based on its own holding information, and transmits it to the SIP server 12 (step S3).

  The SIP server 12 that has received the SIP signal from the SIP server 11 performs the same processing as the processing of the SIP server 11 described above. That is, the SIP server 12 interprets the parameter “d = poweroff” from the SDP information of the received SIP signal (step S4). The SIP server 12 holds the power-off setting by itself. Then, the SIP server 12 interprets the next transmission destination (worker terminal 22) from the request information in the SIP signal and the route information held by itself. Then, the SIP server 12 creates a SIP signal designating “d = poweroff” in the SDP portion based on its own holding information, and transmits it to the worker terminal 22 (step S5).

  The worker terminal 22 that has received the SIP signal from the SIP server 12 transmits a response signal to the received SIP signal to the SIP server 12 (step S6).

  The SIP server 12 that has received the response signal for the SIP signal from the work terminal 22 transmits the response signal to the next response destination SIP server 11 (step S7). Then, the SIP server 12 executes its own power shutdown (step S8).

  The SIP server 11 that has received the response signal for the SIP signal from the SIP server 12 transmits the response signal to the worker terminal 21 that is the next response destination (step S9). Then, the SIP server 11 performs its own power shutdown (step S10).

  If the processing operation of the SIP server does not end normally, the SIP server transmits the data to be transmitted (SIP signal, response signal, or other communication data) including information indicating abnormality. Also good. In addition, when data including information indicating abnormality is received, the SIP server does not have to turn off the power.

  When the worker terminal 21 receives a response signal to the SIP signal from the SIP server 11, the worker can determine whether or not the processing operation of the SIP server on the route R1 has ended normally (step S11). For example, when the response signal does not include information indicating an abnormality, the worker has normally finished the processing operation of the SIP server on the route R1, and has successfully finished the power-off instruction to these SIP servers. Judge.

  As described above, when the processing operation of the SIP server on the route R1 ends normally, the power of all the SIP servers on the route R1 is turned off (step S12).

  FIG. 5 is a block configuration diagram showing the main functional configuration of the SIP server according to the first embodiment of the present invention. The SIP server 11 according to the first embodiment of the present invention includes a data transfer processing unit 111, a power-off information storage processing unit 112, a power-off processing unit 113, a storage unit 114, and a power-off information detection processing unit 115. And.

  The data transfer processing unit 111 transfers communication data such as a SIP signal and a response signal to the SIP signal based on the path information. The SIP signal may be referred to as first communication data. In addition, a response signal to the SIP signal may be referred to as second communication data. The power-off information detection processing unit 115 interprets the SIP signal received by the data transfer processing unit 111. And when the power-off information is included in the SIP signal, the power-off information detection processing unit 115 detects the power-off information from the SIP signal. The power-off information storage processing unit 112 stores the power-off information detected by the power-off information detection processing unit 115 in the storage unit 114.

  The power-off processing unit 113 determines whether the response signal received by the data transfer processing unit 111 is a response to the SIP signal previously received by the data transfer processing unit 111. And when it determines with it being a response, the power-off process part 113 performs a power-off based on the power-off information of the SIP signal corresponding to a response signal. This power-off is performed after the response signal is transferred by the data transfer processing unit 111 to the next transmission destination based on the path information. Note that if the power-off information of the SIP signal corresponding to the response signal does not exist, that is, if the power-off information is not included in the SIP signal, the power-off processing unit 113 does not turn off the power.

  The determination as to whether the response signal received by the data transfer processing unit 111 is a response to the SIP signal previously received by the data transfer processing unit 111 may be performed as follows. First, when receiving a SIP signal, the power-off information storage processing unit 112 stores information for identifying communication data in the storage unit 114 in addition to the power-off information included in the SIP signal. When the response signal is received, the power-off processing unit 113 compares the information for identifying the communication data stored in the storage unit 114 with the similar information included in the response signal to determine whether they match. To do. The information for identifying the communication data is, for example, a unique number given when the SIP signal is created. When a response signal for the SIP signal is created, the same number as the SIP signal is given to the response signal. The

  The SIP server 12 has a functional configuration similar to that of the SIP server 11 as shown in FIG.

  As described above, the network system N1 according to the first embodiment of the present invention can reduce the burden on the operator. The reason is that the power-off processing unit 113 of the SIP server performs power-off based on the power-off information included in the SIP signal received by the SIP server. In other words, in the network system N1, the operator does not need to move to the server installation location and turn off the power, and does not need to manage information for identifying the server. Instead of this, the worker only has to operate the worker terminal 21 and transmit the SIP signal including the power-off information.

  Further, the network system N1 according to the first embodiment of the present invention makes it possible to prevent the SIP server from being powered off accidentally before confirming that it operates normally. The reason is that, when the parameters included in the SIP signal are processed, the power-off processing unit 113 performs power-off of the SIP server itself when the operation of the SIP server ends normally.

  Further, the network system N1 according to the first embodiment of the present invention enables the SIP server to be powered off only when the processing operation of the SIP server on the communication path is normally completed. The reason is that the power-off processing unit 113 of the SIP server performs power-off when it receives a response signal for the previously received SIP signal. That is, if the SIP signal or response signal is not transmitted because the processing operation of the SIP server on the communication path has ended abnormally, the SIP server that was supposed to receive the SIP signal or response signal thereafter will be powered off. Not done.

  In addition, this prevents the SIP server in the middle of the communication path from being turned off because the SIP server in the middle of the communication path is turned off. Can be avoided. For example, when the SIP server 11 is turned off before the SIP server 12 in FIG. 1 is turned off, the communication data transmission path for instructing the SIP server 12 to be turned off from the worker terminal 21 is cut off. Can be avoided. The reason is that the power-off instruction to the SIP server 11 does not end unless the power-off instruction to the SIP server 12 ends normally and the SIP server 12 does not send a response signal to the SIP server 11 to the SIP server 11. It is.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. The second embodiment of the present invention shows an expanded configuration based on the configuration of the network system according to the first embodiment. The SIP protocol in the second embodiment of the present invention enables specification of time in the power-off instruction.

  FIG. 6 is a diagram for explaining the configuration and processing outline of the network system according to the second embodiment of the present invention. The network system N2 according to the second embodiment of the present invention includes worker terminals 21 to 23 and SIP servers 11 to 13.

  The worker terminal 21 and the SIP server 11 are connected to be communicable. Further, the SIP servers 11 and 12, the SIP servers 11 and 13, the SIP server 12 and the worker terminal 22, and the SIP server 13 and the worker terminal 23 are similarly connected. The worker terminals 21 and 22 and the SIP servers 11 and 12 hold route information for performing communication between the worker terminal 21 and the worker terminal 22 (route R1). In addition, the worker terminals 21 and 23 and the SIP servers 11 and 13 hold route information for performing communication between the worker terminal 21 and the worker terminal 23 (route R2).

  In the worker terminals 21 to 23 and the SIP servers 11 to 13, as in the first embodiment, the SIP protocol capable of specifying “power-off information” by extending the SDP portion of the SIP protocol is operating. . Furthermore, in the second embodiment, it is possible to specify time (such as “power-off after 300 seconds”) and time (such as “power-off at 17:00”) when specifying “power-off information”. In the second embodiment, “d = poweroff 300” is described in the SDP portion of the SIP protocol when specifying the time “power is turned off after 300 seconds”. In addition, when the time of “power cut off at 17:00” is specified, “d = poweroff 17:00” is described in the SDP portion of the SIP protocol.

  The SIP servers 11 to 13 have a function of interpreting a parameter “d = poweroff” obtained by extending the SDP portion of the SIP protocol and autonomously powering off the server at a designated time or time.

  FIG. 7 is a diagram illustrating route information held by the SIP server 11. The route information in FIG. 7 indicates that when the transmission destination of the communication data received by the SIP server 11 is the worker terminal 22, the SIP server 11 transfers the communication data to the SIP server 12 that is the next transmission destination. ing. When the transmission destination of the communication data received by the SIP server 11 is the worker terminal 23, the SIP server 11 indicates that the communication data is transferred to the SIP server 13 which is the next transmission destination.

  FIG. 8 is a diagram illustrating a SIP signal transmitted from the worker terminal 21 with the worker terminal 22 as a transmission destination.

  FIG. 9 is a diagram illustrating a SIP signal transmitted from the worker terminal 21 with the worker terminal 23 as a transmission destination.

  FIG. 10 is a sequence diagram illustrating an overview of processing operations of the network system N2 according to the second embodiment of the present invention. Hereinafter, the operation check and power-off processing of the SIP server in the network system N2 will be described with reference to FIGS.

  First, as in the first embodiment, the worker operates the worker terminal 21 to operate the SIP server (SIP server 11) on the route R1 which is a communication route between the worker terminal 21 and the worker terminal 22. , 12) and the power-off process are started.

  First, as shown in FIG. 8, the worker terminal 21 creates a SIP signal in which “d = poweroff 300” is specified in the SDP portion as a power-off instruction (power-off information). Then, the worker terminal 21 transmits the created SIP signal with the worker terminal 22 as a transmission destination. The SIP signal transmitted from the worker terminal 21 is transmitted to the SIP server 11 based on the route information held by the worker terminal 21 (step S1 in FIG. 10).

  The SIP server 11 that has received the SIP signal from the worker terminal 21 interprets the parameter “d = poweroff 300” from the SDP information of the received SIP signal (step S2). That is, a power-off instruction for power-off after 300 seconds is acquired. The SIP server 11 holds the power-off timer setting (300 seconds) by itself. Then, the SIP server 11 interprets the next transmission destination (SIP server 12) from the request information (INVITE worker terminal 22) in the SIP signal in FIG. 8 and the route information in FIG. Then, the SIP server 11 creates a SIP signal designating “d = poweroff 300” in the SDP portion based on its own holding information, and transmits it to the SIP server 12 (step S3).

  The SIP server 12 that has received the SIP signal from the SIP server 11 performs the same processing as the processing of the SIP server 11 described above. That is, the SIP server 12 interprets the parameter “d = poweroff 300” from the SDP information of the received SIP signal (step S4). That is, a power-off instruction for power-off after 300 seconds is acquired. The SIP server 12 holds the power-off timer setting (300 seconds) by itself. Then, the SIP server 12 interprets the next transmission destination (worker terminal 22) from the request information in the SIP signal and the route information held by itself. Then, the SIP server 12 creates a SIP signal specifying “d = poweroff 300” in the SDP portion based on its own holding information, and transmits it to the worker terminal 22 (step S5).

  The worker terminal 22 that has received the SIP signal from the SIP server 12 transmits a response signal to the received SIP signal to the SIP server 12 (step S6).

  The SIP server 12 that has received the response signal for the SIP signal from the work terminal 22 transmits the response signal to the next response destination SIP server 11 (step S7). Then, the SIP server 12 sets a power-off timer (300 seconds) in itself (step S8). Note that the downward triangle written on the lower side of the square frame in step S8 in FIG. 10 represents a state in which the set power-off timer count proceeds from the upper side to the lower side in the figure. The upper edge of the triangle indicates when the timer starts, and the lower vertex indicates when the timer expires. The same applies to the other downward triangles in FIG.

  The SIP server 11 that has received the response signal for the SIP signal from the SIP server 12 transmits the response signal to the worker terminal 21 that is the next response destination (step S9). Then, the SIP server 11 sets a power-off timer (300 seconds) in itself (step S10).

  When the worker terminal 21 receives a response signal to the SIP signal from the SIP server 11, the worker can determine whether or not the processing operation of the SIP server on the route R1 has ended normally (step S11).

  Next, the worker operates the worker terminal 21 to confirm the operation and power of the SIP server (SIP servers 11 and 13) on the route R2, which is a communication route between the worker terminal 21 and the worker terminal 23. The disconnection process is started.

  First, as shown in FIG. 9, the worker terminal 21 creates a SIP signal in which “d = poweroff 400” is specified in the SDP portion as a power-off instruction. Then, the worker terminal 21 transmits the created SIP signal with the worker terminal 23 as a transmission destination. The SIP signal transmitted from the worker terminal 21 is transmitted to the SIP server 11 based on the route information held by the worker terminal 21 (step S12).

  The SIP server 11 that has received the SIP signal from the worker terminal 21 resets the timer because the power-off timer (300 seconds) set in step S10 has not expired. The power-off is canceled (step S13). Then, the SIP server 11 interprets the parameter “d = poweroff 400” from the SDP information of the received SIP signal (step S14). That is, a power-off instruction to turn off the power after 400 seconds is acquired. The SIP server 11 holds the power-off timer setting (400 seconds) by itself. Then, the SIP server 11 interprets the next transmission destination (SIP server 13) from the request information (INVITE worker terminal 23) in the SIP signal in FIG. 9 and the route information in FIG. Then, the SIP server 11 creates a SIP signal specifying “d = poweroff 400” in the SDP portion based on its own holding information, and transmits it to the SIP server 13 (step S15).

  The SIP server 12 executes its own power-off as the power-off timer (300 seconds) set in step S8 expires (step S16).

  The SIP server 13 that has received the SIP signal from the SIP server 11 interprets the parameter “d = poweroff 400” from the SDP information of the received SIP signal (step S17). The SIP server 13 holds the power-off timer setting (400 seconds) by itself. Then, the SIP server 13 interprets the next transmission destination (worker terminal 23) from the request information in the SIP signal and the route information held by itself. Then, the SIP server 13 creates a SIP signal designating “d = poweroff 400” in the SDP portion based on its own retained information, and transmits it to the worker terminal 23 (step S18).

  The worker terminal 23 that has received the SIP signal from the SIP server 13 transmits a response signal to the received SIP signal to the SIP server 13 (step S19).

  The SIP server 13 that has received the response signal for the SIP signal from the work terminal 23 transmits the response signal to the SIP server 11 that is the next response destination (step S20). Then, the SIP server 13 sets a power-off timer (400 seconds) in itself (step S21).

  The SIP server 11 that has received the response signal for the SIP signal from the SIP server 13 transmits the response signal to the worker terminal 21 that is the next response destination (step S22). Then, the SIP server 11 sets a power-off timer (400 seconds) in itself (step S23).

  When the worker terminal 21 receives a response signal to the SIP signal from the SIP server 11, the worker can determine whether or not the processing operation of the SIP server on the route R2 has ended normally (step S24).

  The SIP server 13 executes its own power-off as the power-off timer (400 seconds) set in step S21 expires (step S25). Similarly, when the power-off timer (400 seconds) set in step S23 expires, the SIP server 11 executes its own power-off (step S26).

  As described above, when the processing operations of the SIP servers on the routes R1 and R2 are normally completed, the power-off of all the SIP servers on the routes R1 and R2 is performed when the power-off timer of each SIP server expires. (Step S27).

  The main functional configurations of the SIP servers 11 to 13 according to the second embodiment of the present invention are the same as those shown in FIG. Note that the power-off processing unit 113 of the SIP server according to the second embodiment of the present invention has a function of performing power-off based on time or time included in the power-off information.

  As described above, the network system N2 according to the second embodiment of the present invention can perform the power-off after the specified time has elapsed or at the specified time in addition to the functions in the first embodiment. To do.

[Third Embodiment]
Next, a third embodiment of the present invention will be described. The third embodiment of the present invention shows the basic configuration of the configuration common to the first and second embodiments.

  FIG. 11 is a block configuration diagram showing the main functional configuration of a network device according to the third embodiment of the present invention. A network device 31 according to the third embodiment of the present invention includes a data transfer processing unit 311, a power-off information storage processing unit 312, a power-off processing unit 313, and a storage unit 314.

  The network device 31 may be a computer such as a server or a dedicated device such as a router device. The storage unit 314 may be provided outside the network device 31.

  The data transfer processing unit 311 includes first communication data that is data transmitted from a certain transmission source to a certain transmission destination, and response data of the first communication data that is transmitted from the above transmission destination to the above transmission source. The second communication data is transferred based on the route information. When the first communication data includes power-off information for instructing power-off, the power-off information storage processing unit 312 stores the power-off information in the storage unit 314. The power-off processing unit 313 determines whether or not the second communication data is response data of the first communication data, and performs power-off based on the power-off information when it is determined that the second communication data is response data. .

  Thus, the network device according to the third embodiment of the present invention makes it possible to reduce the burden on the operator. The reason is that the power-off processing unit 313 performs power-off based on the power-off information included in the first communication data received by the data transfer processing unit 311. That is, the operator does not need to move to the place where the network device is installed and turn off the power, and does not need to manage information for identifying the network device.

  In the first and second embodiments described above, the SIP server 11 acquires the power-off information from the SIP signal, but may instead acquire it from a response signal to the SIP signal. That is, the SIP server 11 may not store the power-off information when receiving the SIP signal, but may acquire the power-off information from the response signal and receive the power-off when receiving the response signal. In this case, if the response signal does not include the power-off information, the power-off processing unit 113 does not turn off the power.

  Similarly, in the third embodiment described above, the network device 31 acquires the power-off information from the first communication data, but may instead acquire it from the second communication data. That is, when the network device 31 receives the first communication data, the network device 31 does not store the power-off information. When the network device 31 receives the second communication data, the network device 31 acquires the power-off information from the second communication data and May be performed. In this case, if the power-off information is not included in the second communication data, the power-off processing unit 113 does not turn off the power.

  The SIP server and network device in the first to third embodiments described above may be realized by dedicated hardware or may be realized by executing a software program in a computer.

  FIG. 12 is a block diagram illustrating an example of elements constituting the computer. 12 includes a CPU (Central Processing Unit) 910, a RAM (Random Access Memory) 920, a ROM (Read Only Memory) 930, a storage medium 940, and a communication interface 950. The components of the SIP server 11 and the network device 31 described above may be realized by executing a program in the CPU 910 of the computer 900. Specifically, the components of the SIP server 11 and the network device 31 described in FIGS. 5 and 11 may be realized by the CPU 910 reading and executing a program from the ROM 930 or the storage medium 940. In such a case, the present invention is configured by a computer program code or a storage medium (for example, a storage medium 940 or a removable memory card not shown) in which the computer program code is stored. .

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

(Appendix 1)
First communication data that is data transmitted from the transmission source to the transmission destination, and second communication data that is a response to the first communication data transmitted from the transmission destination to the transmission source Data transfer processing means for transferring
When the first communication data includes power-off information for instructing power-off, the power-off information storage processing unit stores the power-off information in a predetermined storage unit;
Determining whether or not the second communication data is a response to the first communication data; and when determining that the second communication data is a response, power-off processing means for performing power-off based on the power-off information. Network equipment provided.

(Appendix 2)
First communication data that is data transmitted from the transmission source to the transmission destination, and second communication data that is a response to the first communication data transmitted from the transmission destination to the transmission source Data transfer processing means for transferring
It is determined whether or not the second communication data is a response to the first communication data. The second communication data is determined to be a response, and the second communication data includes power-off information instructing power-off. A network device comprising: a power-off processing unit that performs power-off based on the power-off information.

(Appendix 3)
The power-off information includes information on time or time,
The network device according to appendix 1 or 2, wherein the power-off processing unit performs power-off after the elapse of time or at the time.

(Appendix 4)
The network device according to any one of appendices 1 to 3, further comprising power-off information detection processing means for detecting the power-off information from the first communication data or the second communication data.

(Appendix 5)
5. The network device according to any one of appendices 1 to 4, which is a SIP (Session Initiation Protocol) server.

(Appendix 6)
The network device according to any one of appendices 1 to 5,
A network system comprising an information processing apparatus.

(Appendix 7)
A network device that is on the communication path between the source and destination
Transferring first communication data that is data transmitted from the transmission source to the transmission destination;
Transferring the second communication data, which is a response of the first communication data, transmitted from the transmission destination to the transmission source;
It is determined whether or not the second communication data is a response to the first communication data, the response is determined to be a response, and the first communication data or the second communication data is instructed to be turned off. A power control method for a network device that performs power-off of the network device itself based on the power-off information when the power-off information is included.

(Appendix 8)
The power-off information includes information on time or time,
The network device power control method according to appendix 7, wherein the power cut-off is performed after the elapse of time or at the time.

(Appendix 9)
The network device power control method according to appendix 7 or 8, wherein the network device detects the power-off information from the first communication data or the second communication data.

(Appendix 10)
10. The power control method for a network device according to any one of appendices 7 to 9, wherein the network device is a SIP (Session Initiation Protocol) server.

(Appendix 11)
To the computer of the network device intervening on the communication path between the source and destination,
Transferring first communication data that is data transmitted from the transmission source to the transmission destination;
Transferring the second communication data, which is a response of the first communication data, transmitted from the transmission destination to the transmission source;
It is determined whether or not the second communication data is a response to the first communication data, the response is determined to be a response, and the first communication data or the second communication data is instructed to be turned off. A program for executing a process of powering off the network device itself based on the power-off information when power-off information to be included is included.

(Appendix 12)
The power-off information includes information on time or time,
The program according to claim 11, wherein the power-off is performed after the elapse of time or at the time.

(Appendix 13)
The program according to appendix 11 or 12, which causes a computer of the network device to execute processing for detecting the power-off information from the first communication data or the second communication data.

(Appendix 14)
14. The program according to any one of appendices 11 to 13, wherein the network device is a SIP (Session Initiation Protocol) server.

11, 12, 13 SIP server 21, 22, 23 Worker terminal 31 Network device 111, 311 Data transfer processing unit 112, 312 Power-off information storage processing unit 113, 313 Power-off processing unit 114, 314 Storage unit 115 Power-off information Detection processing unit 900 computer 910 CPU
920 RAM
930 ROM
940 Storage medium 950 Communication interface N1, N2 Network system R1, R2 Route

Claims (9)

First communication data that is data transmitted from the transmission source to the transmission destination, and second communication data that is a response to the first communication data transmitted from the transmission destination to the transmission source Data transfer processing means for transferring
When the first communication data includes power-off information for instructing power-off, the power-off information storage processing unit stores the power-off information in a predetermined storage unit;
Determining whether or not the second communication data is a response to the first communication data; and when determining that the second communication data is a response, a power-off processing unit that performs power-off based on the power-off information. SIP (Session Initiation Protocol) server provided . First communication data that is data transmitted from the transmission source to the transmission destination, and second communication data that is a response to the first communication data transmitted from the transmission destination to the transmission source Data transfer processing means for transferring
It is determined whether or not the second communication data is a response to the first communication data. The second communication data is determined to be a response, and the second communication data includes power-off information instructing power-off. In this case, a SIP server comprising: a power-off processing unit that performs power-off based on the power-off information. The power-off information includes information on time or time,
The SIP server according to claim 1, wherein the power-off processing unit performs power-off after the elapse of time or at the time. The SIP server according to any one of claims 1 to 3, further comprising a power-off information detection processing unit that detects the power-off information from the first communication data or the second communication data. A SIP server according to any one of claims 1 to 4 ;
A network system comprising an information processing device. A network device that is on the communication path between the source and destination
Transferring first communication data that is data transmitted from the transmission source to the transmission destination;
Transferring the second communication data, which is a response of the first communication data, transmitted from the transmission destination to the transmission source;
It is determined whether or not the second communication data is a response to the first communication data, the response is determined to be a response, and the first communication data or the second communication data is instructed to be turned off. A power control method for a network device that performs power-off of the network device itself based on the power-off information when the power-off information is included. The power-off information includes information on time or time,
The network device power control method according to claim 6 , wherein the power-off is performed after the elapse of time or at the time. To the computer of the network device intervening on the communication path between the source and destination,
A process of transferring first communication data which is data transmitted from the transmission source to the transmission destination;
A process of transferring second communication data, which is a response to the first communication data, transmitted from the transmission destination to the transmission source;
It is determined whether or not the second communication data is a response to the first communication data, the response is determined to be a response, and the first communication data or the second communication data is instructed to be turned off. A program for executing a process of powering off the network device itself based on the power-off information when power-off information to be included is included. The power-off information includes information on time or time,
The program according to claim 8 , wherein the power-off is performed after the elapse of time or at the time.

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