JP5232108B2 - Communication system, master unit and slave unit - Google Patents

Description

  The present invention relates to a communication system that connects devices using an IP (Internet Protocol) address, and more particularly to a technology for connecting using a dynamic IP address assigned to a device.

For example, all devices connected to the Internet are assigned an IP address for identifying the device, and connection between devices is realized by using this IP address. The IP address includes a fixed IP address assigned in advance and a dynamic IP address assigned dynamically. As a conventional method for connecting between devices, the remote monitoring system (communication system) disclosed in Patent Document 1 uses a dynamic IP address assigned to a home device (child device) connected to the Internet as a server device (master device). The server device is configured to connect to the in-home device based on the dynamic IP address.
In the information supply system (communication system) disclosed in Patent Document 2, for example, when a communication line is disconnected, a monitoring terminal (based on a fixed IP address of a management computer (master unit) registered in advance is used. (Slave unit) is configured to transmit the new dynamic IP address to the management computer in order to request the management computer to register the newly assigned dynamic IP address.

JP 2005-318446 A JP 2004-7597 A

In the dynamic IP address notification process disclosed in Patent Document 1, the slave unit notifies the slave unit's dynamic IP address regardless of the state of the master unit. However, under a situation where a failure such as a power failure occurs on the base unit side, for example, the dynamic IP address may not reach the base unit, and the base unit may not be able to register the dynamic IP address. . Similarly, in a situation where a failure has occurred on the parent device side, even the parent device disclosed in Patent Document 2 may not be able to register the dynamic IP address of the child device. In such a case, if the failure recovers after that, communication between the master unit and the slave unit should be recovered quickly. However, in the master unit, the dynamic IP address of the registered slave unit due to the previous failure Since the dynamic IP address assigned to the handset may have been changed while the failure occurred, it will eventually be sent from the handset. There was a need to wait for a dynamic IP address registration request again. That is, the conventional communication system has a problem that the latest dynamic IP address cannot be registered quickly when a failure occurs on the base side.
Further, in the communication system disclosed in Patent Document 1, since image data acquired from the slave unit is not transmitted from the master unit to each slave unit, there is a service that effectively uses bidirectional communication between the master unit and the slave unit. Not done.

  Therefore, the present invention provides a communication system that enables quick registration of the latest dynamic IP address for realizing communication between a parent device and a child device, even when a failure occurs on the parent device side, An object is to provide a machine and a child machine.

  A communication system for solving the above problems includes one or more parent devices connected to a network network using a fixed IP address, and a plurality of child devices connected to the network network using dynamic IP addresses. Each of the plurality of slave units regularly performs storage processing for storing the fixed IP address in advance and notification processing for performing notification of the dynamic IP address to the fixed IP address A first notification unit that executes automatically, a monitoring unit that monitors whether a response transmitted from the parent device in response to a notification of a dynamic IP address performed based on the notification process, A second notification unit that executes the notification process by changing to a time interval shorter than the regular time interval in the first notification unit when there is no response from the parent device, , Above When there is a notification of a dynamic IP address performed based on the processing, a receiving unit that receives the notification, a registration unit that registers the notified dynamic IP address, and a response to the slave in response to the notification And a response unit for addressing the registered dynamic IP address.

  According to this communication system, when there is no response from the master unit, the notification of the dynamic IP address is made shorter than the regular time interval, so that when the master unit returns, the slave unit is connected. Dynamic IP addresses for can be quickly registered.

  In addition, a master unit for solving the above problems is connected to a slave unit connected to a network network using a dynamic IP address via the network network, and connected to the network network using a fixed IP address. A receiving unit that receives the notification when the dynamic IP address is notified directly from the slave unit or via the router from the slave unit, and the notified dynamic unit A registration unit that registers an IP address; and a response unit that sends a response to the slave to the notification to the registered dynamic IP address. The notification of the dynamic IP address is performed periodically. If a response is not made to the slave unit, the notification of the dynamic IP address is performed at a time interval shorter than a regular time interval.

  According to this master unit, when a response to the slave unit is not made, a dynamic IP address is notified at a short time interval so that when the master unit returns, Dynamic addresses can be registered quickly.

  In addition, a slave unit for solving the above problems is connected to a master unit connected to a network using a fixed IP address via the network, and connected to the network using a dynamic IP address. A storage unit that stores the fixed IP address in advance, a first notification unit that periodically performs notification processing for performing notification of the dynamic IP address to the fixed IP address, In response to the notification of the dynamic IP address performed based on the notification process, a monitoring unit that monitors whether a response transmitted from the parent device has been received, and when there is no response from the parent device A second notification unit that changes the time interval to a shorter time interval than the regular time interval in the first notification unit and performs the notification process.

  According to this slave unit, even if there is no response from the master unit, the master unit can be recovered by performing a notification process for notifying a dynamic IP address shorter than a regular time interval. In this case, a dynamic IP address for connecting to the slave unit can be quickly registered.

  According to the present invention, the latest dynamic IP address can be quickly registered when the parent device returns even if a failure occurs on the parent device side that receives the notification of the dynamic IP address.

It is a figure which shows the structure of the communication system of 1st Embodiment. It is a block diagram which shows the function of a main | base station. It is a block diagram which shows the function of a subunit | mobile_unit. 5 is a flowchart illustrating an overall operation when a dynamic IP address is registered in a parent device in the first embodiment. It is a figure which shows the structure of the communication system of 2nd Embodiment. It is a figure which shows the structure of the communication system of 3rd Embodiment. It is a block diagram which shows the function of the subunit | mobile_unit of 3rd Embodiment. 14 is a flowchart illustrating an overall operation when a dynamic IP address is registered in a parent device in the third embodiment.

<First Embodiment>
Hereinafter, an embodiment of a communication system of the present invention will be described with reference to the drawings. The communication system according to the embodiment includes a network adapter that transmits data such as audio and video using IP (Internet Protocol) packets (hereinafter simply referred to as “packets”) that can be communicated via a network.

[Configuration of communication system]
FIG. 1 is a diagram showing a configuration of a communication system 1 including a network adapter as a parent device and a network adapter as a child device under its management.
In the communication system 1 shown in FIG. 1, a network adapter 10 (hereinafter referred to as “parent device 10”) as a parent device, and network adapters 20a,. (Hereinafter referred to as “slave devices 20, 20n”) is configured to be able to communicate with an ISP (Internet Service Provider), and each ISP is connected to the network 30.

  Further, a microphone 12 is connected to the parent device 10 via an amplifier 11, and an audio signal collected from the microphone 12 is amplified and input to the parent device 10. Base unit 10 generates a packet including the input audio signal and transmits the packet to each of a plurality of slave units 20a and 20n via network 30. Amplifiers 21a and 21n for outputting audio from the speakers 22a and 22n are connected to the plurality of slave units 20a and 20n. Is loudened from the speakers 22a and 22n.

In the communication system 1, in order to realize a connection (for example, simultaneous broadcasting using audio data) between the parent device 10 and each of the child devices 20a and 20n, a packet using a fixed IP address and a dynamic IP address is used. Transmission takes place. The transmission of the packet is performed directly between the parent device 10 and each of the child devices 20a and 20n according to, for example, TCP (Transmission Control Protocol) / IP (Internet Protocol).
Specifically, each of the slave units 20a and 20n stores in advance the fixed IP address of the master unit 10, and periodically transmits a packet to the fixed IP address. At this time, each slave unit 20a, 20n notifies the assigned dynamic IP address. When receiving the notification of the dynamic IP address of each child device from each of the child devices 20a and 20n, the parent device 10 registers each dynamic IP address and sends a packet to each dynamic IP address. . The registration process of the dynamic IP packet in the master unit 10 and the notification process of the dynamic IP address in the slave units 20a and 20n will be described later.

  FIG. 1 shows a case where a dynamic IP address is assigned to the slave units 20a and 20n connected to the ISP in accordance with an external DHCP (Dynamic Host Configuration Protocol) server (not shown). Further, FIG. 1 shows a case where a fixed IP address is assigned to the base unit 10 connected to the ISP according to an external DHCP server (not shown).

  In the communication system 1, the base unit 10 executes data processing, timing processing, and transmission processing in the base unit 10 in addition to audio data compression processing and decompression processing. For example, the base unit 10 transmits the audio data collected by the microphone 12 or the audio data received from a certain slave unit to the plurality of slave units 20a and 20n at the same time to realize simultaneous broadcasting. It has a known broadcast function. With this broadcast function, the master unit 10 transmits the voice data used for the broadcast to the plurality of slave units 20a and 20n, thereby broadcasting the voice data through the slave units 20a and 20n.

  Next, the configuration of the parent device 10 and the plurality of child devices 20a and 20n shown in FIG. 1 will be described with reference to FIGS. In the following description, each slave unit is simply referred to as the slave unit 20 in the description common to each of the plurality of slave units.

[Base unit 10]
FIG. 2 is a block diagram for explaining the functions of base unit 10. This function is realized by a CPU (not shown) executing a program stored in a storage device (not shown).
2 includes a reception unit 201, a registration unit 202, a response unit 203, and a management table 2021.

  The receiving unit 201 receives notifications from the plurality of slave units 20 via the network 30. This notification is performed for the purpose of registering the latest dynamic IP address assigned to the child device 20 in the parent device 10. The packet for this notification includes the fixed IP address of the parent device 10 as information for specifying the destination and the dynamic IP address of the child device 20 as information for specifying the transmission source. The dynamic IP address of the child device 20 is associated with a host name as a domain name indicating the child device 20.

The registration unit 202 registers the dynamic IP address of each child device notified from the plurality of child devices 20. This registration is performed using, for example, the management table 2021.
The management table 2021 is provided for managing the dynamic IP address of the child device 20. As shown in FIG. 2, the management table 2021 records the host name (in the example of FIG. 2, the name of a specific branch in the company where the handset 20 is installed) and the dynamic IP address of the handset 20. Has been.

  The response unit 203 responds to notifications from the plurality of slave units 20 to the registered dynamic IP addresses of the slave units 20. This reply is made not only for the purpose of notifying that the latest dynamic IP address has arrived at the parent device 10, but also for the purpose of monitoring whether or not a failure has occurred on the parent device 10 side in this embodiment. Here, the failure on the parent device 10 side is a failure in which the dynamic IP address cannot be registered in the parent device 10. For example, as a failure on the parent device 10 side, a reboot of the parent device 10, a power failure, an uncontrollable state, a congestion state of the network 30 and the like are assumed.

  The packet for this reply includes the dynamic IP address of the child device 20 as information specifying the destination and the fixed IP address of the parent device 10 as information specifying the transmission source. Further, this packet may include, for example, information (a flag or the like) as a response indicating that the dynamic IP address registration of the child device 20 included in the notification is successful. In this case, it is possible to determine whether or not the dynamic IP address registration has succeeded in the slave unit 20.

[Slave 20]
FIG. 3 is a block diagram for explaining the function of the slave unit 20. This function is realized by a CPU (not shown) executing a program stored in a storage device (not shown).
The subunit | mobile_unit 20 shown in FIG. 3 is provided with the memory | storage part 301, the acquisition part 302, the 1st notification part 303, the monitoring part 304, the 2nd notification part 305, the switch part 306, the alerting | reporting part 307, and the stop part 308.

  Storage unit 301 stores a fixed IP address of base unit 10 in advance.

  The acquisition unit 302 acquires a dynamic IP address of itself (own device) dynamically allocated by a DHCP server (external device) (not shown). For example, the acquisition unit 302 transmits a request packet for requesting acquisition of a dynamic IP address to the ISP, and receives its own dynamic IP packet from a DHCP server (not shown) that has received the request packet. The value of the dynamic IP address for realizing the connection to the network 30 is not fixed but dynamically changes according to the DHCP server allocation process.

The first notification unit 303 periodically performs notification processing for performing notification of the assigned dynamic IP address to the fixed IP address of the parent device 10. Since the slave unit 20 of this embodiment acquires its own dynamic IP address from a DHCP server (not shown), in this notification process, the notification of the dynamic IP address is a fixed IP address directly from the first notification unit 303. To be addressed. This dynamic IP address is registered in the parent device 10. A periodic time interval for notification of a dynamic IP address performed based on communication processing is set to such an extent that dynamic IP address registration can be appropriately performed. In this embodiment, for example, the periodic time interval of the dynamic IP address is 60 s or 10 s.
The regular time interval is not limited to the example described above, and can be set from various viewpoints. For example, the notification of the dynamic IP address may be performed when the acquisition unit 302 receives the dynamic IP address of the child device 20 from a DHCP server (not shown), It may be performed when information (for example, voice data) is transmitted.

The monitoring unit 304 monitors whether or not a response transmitted from the parent device 10 has been received in response to the notification of the dynamic IP address. This monitoring is performed not only for the purpose of determining whether or not the dynamic IP address of the child device 20 has reached the parent device 10, but also for the purpose of determining whether or not a failure has occurred on the parent device 10 side. For example, when a response is received, the monitoring unit 304 determines that the notification from the child device 20 has reached the parent device 10. On the other hand, when no reply is received, the monitoring unit 304 determines that a failure has occurred on the parent device 10 side. The monitoring unit 304 manages an allowable period from when the dynamic IP address is notified (after the notification process is executed) until the response is received, that is, the longest period during which the response can be received. Yes. For example, when the longest period is reached, the monitoring unit 304 determines that there is no response.
The longest period is set based on, for example, the network environment (communication speed or the like) between each child device 20 and the parent device 10.

  The second notification unit 305 notifies the dynamic IP address of the child device 20 when there is no response from the parent device 10, that is, when the monitoring unit 304 determines that there is no response from the parent device 10. The interval is changed to a time interval shorter than the regular time interval in the first notification unit 303. Then, the second notification unit 305 performs the notification process, that is, notifies the dynamic IP address of the child device 20 to the fixed IP address of the parent device 10. In this embodiment, the notification of the dynamic IP address is performed for the purpose of communication recovery processing accompanying a failure on the base unit 10 side. Specifically, the notification of the dynamic IP address is performed at a time shorter than the regular time interval described above. In this embodiment, for example, 5 s is set when the regular time interval is 60 s, or 1 s when the regular time interval is 10 s. Thereby, if the failure on the base unit 10 side is recovered, the registration of the dynamic IP address in the base unit 10 can be completed early.

  When the second notification unit 305 notifies the dynamic IP address, the switching unit 306 receives a response from the parent device 10, that is, the monitoring unit 304 receives a response from the parent device 10. When the determination is made, the notification by the second notification unit 305 is switched to the notification by the first notification unit 303. Thereby, the notification of the dynamic IP address is performed at regular time intervals (for example, 60 s).

  When there is no response from the parent device 10, that is, when the monitoring unit 304 determines that there is no response from the parent device 10, the notification unit 307 notifies that there is no response. Specifically, this notification is performed by the notification unit 307 transmitting a message indicating that there is no response from the parent device 10 to, for example, a personal computer (not shown). As a result, a personal computer (not shown) can notify the user by displaying or outputting a message indicating that there is no response from the parent device 10. Or the alerting | reporting part 307 may alert | report to a user by making a contact output with respect to the rotating lamp which is not shown in figure, and making it light.

  When there is no response from the master unit 10 when the master unit 10 requests transmission of predetermined information (for example, voice data in the slave unit 20), the stop unit 308 (the monitoring unit 304 sets When it is determined that there is no response from the machine 10, the transmission of the predetermined information is stopped. Thereby, transmission of predetermined information stops.

[Operation of communication system]
Next, the overall operation of the communication system of this embodiment will be described with reference to FIG.
FIG. 4 is a flowchart showing the overall operation when the dynamic IP address notified from the slave unit is registered in the master unit. In FIG. 4, as an example, the overall operation of the communication system 1 when the slave device 20 notifies the master device 10 of a dynamic IP address is shown.
In FIG. 6, first, the slave unit 20 (acquisition unit 302) acquires a dynamic IP address from, for example, an ISP DHCP server (step S101).

  The slave device 20 (first notification unit 303) performs notification processing (first notification processing) for notifying the master device 10 via the network 30 of the dynamic IP address, that is, its own dynamic IP. Address notification is performed periodically (step S102). For this purpose, the first notification unit 303 reads the fixed IP address of the parent device 10 from the storage unit 301, the fixed IP address (destination IP address), and the dynamic IP address (source IP address) of the child device 20. Is transmitted to the base unit 10. In this example of the entire operation, since the time interval for periodically reporting is 60 ms, the dynamic IP address of the slave unit 20 is notified at an interval of 60 ms in step S102.

  As a result, when the parent device 10 (receiving unit 201) receives the dynamic IP address of the child device 20 (YES in step S103), the parent device 10 (registration unit 202) receives the dynamic IP address. Registration processing is performed (step S104). For this purpose, the registration unit 202 registers the dynamic IP address described in the transmission source IP address of the packet received in step S103 in the management table 2021. In this example of the overall operation, since the dynamic IP address is associated with the host name, the registration unit 202 refers to the management table 2021 and registers the host name and the dynamic IP address in association with each other. To do. Thereby, thereafter, the base unit 10 can perform communication by designating the handset 20 as a destination.

Then, base unit 10 (response unit 203) performs response processing corresponding to the notification to slave unit 20 that has notified the dynamic IP address via network 30 (step S105). Therefore, the reply unit 203 sends a packet including the dynamic IP address (destination IP address) of the slave unit 20 registered in step S104 and the fixed IP address (source IP address) of the master unit 10 to the slave unit 20. Send.
Note that, for example, when the parent device 10 performs a reboot process as a failure on the parent device 10 side, the parent device 10 cannot perform the processes of steps S103, S104, and S105, and immediately performs the reboot process. After the reboot is completed, the information (host name, dynamic IP address) already registered in the management table 2021 is deleted, so that the parent device 10 cannot connect to any child device 20.

  The subunit | mobile_unit 20 (monitoring part 304) monitors whether the reply processed by step S105 was received (step S106). As a result, when it is determined that a response has not been received (NO in step S106), the slave unit 20 (second notification unit 305) transmits a dynamic IP to the master unit 10 via the network 30. A notification process (second notification process) for notifying an address, that is, a dynamic IP address is notified by shortening the time interval notified in step S102 (60 ms in the example of FIG. 4) (step S107). For this purpose, the second notification unit 305 also reads out the fixed IP address of the parent device 10 from the storage unit 301, the fixed IP address (destination IP address), and the dynamic IP address (source IP address) of the child device 20. Is transmitted to the base unit 10. In this example of the entire operation, the second notification unit 305 notifies at an interval of 5s that is 55s shorter than the time interval notified at step S102. Thereby, the main | base station 10 can register the dynamic IP address of the subunit | mobile_unit 20 rapidly.

  Although not shown in FIG. 4, if it is determined in step S106 that there is no response, handset 20 (notification unit 307) sends a message indicating that there is no response to, for example, a personal computer (not shown). It is preferable to transmit (inform). As a result, a personal computer (not shown) displays a message indicating that there is no response from the parent device 10 or outputs a voice to notify the user and prompts the user to recover from the failure on the parent device 10 side.

  If it is determined in step S106 that there is no response, when the slave unit 20 is transmitting predetermined information (voice data in the example of FIG. 4) to the master unit 10, the slave unit 20 ( The stopping unit 308) preferably stops transmission of audio data, for example. As a result, when there is a failure on the parent device 10 side, information other than the notification from the child device 20 is not transmitted, and the notification from the child device 20 is urged to reach the parent device 10. It is expected that the communication state between the slave unit 20 and the slave unit 20 will be improved early.

  Here, when the failure on the parent device 10 side is recovered (in the example of FIG. 4, the reboot is completed), the parent device 10 performs steps S <b> 103 to S <b> 105. That is, base unit 10 receives the dynamic IP address of slave unit 20 included in the notification from slave unit 20 (YES in step S103), and registers the dynamic IP address in management table 2021 (step S104). ), The above reply process is performed on the slave unit 20 (step S105). Thereafter, the master unit 10 can communicate with the slave unit 20 by designating the dynamic IP address of the slave unit 20 as a destination.

  If the slave unit 20 (monitoring unit 304) determines that a response has been received in step S106 (YES), the slave unit 20 (monitoring unit 304) determines whether or not the reception is during the second notification process. Determination is made (step S108). As a result, if the second notification process is in progress (YES in step S108), the slave unit 20 (switching unit 306) notifies the dynamic IP address notification by the first notification unit 303 (in the example of FIG. 4, 60s). To the interval). The process notified by the first notification unit 303 after switching is the same as step S102.

  As described above, in the communication system 1 according to the present embodiment, each of the plurality of slave units 20 periodically notifies its own dynamic IP address to the master unit 10 and responds to the notification. If there is no response from the base unit 10, the notification is performed by changing the time interval for notifying the dynamic IP address to a time interval shorter than the regular time interval. Thereby, when a failure occurs on the parent device 10 side, the dynamic IP address of each child device for the parent device 10 to connect to each child device 20 is quickly registered.

Second Embodiment
Next, other embodiments of the communication system according to the present invention will be described, in particular, differences from the first embodiment. The communication system of the present embodiment is the same as that of the first embodiment shown in FIG. 1 in that it includes a parent device and a child device, but the network device applied as the parent device and the child device is the first embodiment. Different from that.
In this embodiment, a monitoring camera is applied as a child device, and a management server that centrally manages the monitoring cameras is applied as a parent device.
Below, the structure of the main | base station and the subunit | mobile_unit in this embodiment is demonstrated centering on the difference with the thing of 1st Embodiment.

FIG. 5 shows the configuration of the communication system 1a of the present embodiment. As shown in FIG. 5, in this communication system 1a, a management server 40 as a master unit and a plurality of monitoring cameras 50a,..., 50n are communicably connected in the ISP, and the ISP is connected to the network 30. It is connected.
In the following description, similarly to the description of the first embodiment, each monitoring camera is simply referred to as the monitoring camera 50 in the description common to each of the plurality of monitoring cameras 50a,.

The monitoring camera 50 performs not only image capturing, compression and transmission processing but also sound capturing, compression and transmission processing.
In addition to image data processing, the management server 40 executes audio data processing, timing processing, transmission processing, and the like. For example, when the management server 40 makes a transmission request for image data (including audio data) to the monitoring camera 50, the monitoring camera 50 that has received the transmission request sends the captured image data to the management server 40. Send. Thereby, the management server 40 can display the image captured by the monitoring camera 50.
In FIG. 6, the management server 40 includes the functions as the master unit shown in FIG. 2, that is, the receiving unit 201, the registration unit 202, the response unit 203, and the management table 2021.
The monitoring camera 50 functions as a slave shown in FIG. 3, that is, a storage unit 301, an acquisition unit 302, a first notification unit 303, a monitoring unit 304, a second notification unit 305, a switching unit 306, a notification unit 307, and A stop unit 308 is provided.

  In the communication system 1a of the present embodiment, the overall operation when the dynamic IP address notified from the monitoring camera 50 is registered in the management server 40 is the same as steps S101 to S109 in FIG. Therefore, even in the communication system 1a that enables image monitoring, the same operations and effects as the communication system 1 of the first embodiment can be obtained.

<Third Embodiment>
Next, the communication system of 3rd Embodiment is demonstrated.
The communication system of this embodiment has the same configuration as that of the first embodiment shown in FIG. 1 except that a network adapter as a master unit and a network adapter as a slave unit are the same as those of the first embodiment shown in FIG. The configuration in which the parent device and the child device are connected to the network via the “router” is different from that of the first embodiment.
Below, the structure of the communication system in this embodiment is demonstrated centering on the difference with the thing of 1st Embodiment. First, the configuration of the communication system of the present embodiment will be described with reference to FIG.

[Configuration of communication system]
FIG. 6 is a block diagram illustrating a configuration of a communication system 1b according to the third embodiment. As shown in FIG. 6, the communication system 1b includes a plurality of network adapters 70a,..., 70n, and a network adapter 60 that centrally manages these network adapters. In this communication system 1b, unlike the first embodiment (see FIG. 1), a network adapter 60 as a master unit is connected to the network 30 via a first router 80, and each network as a slave unit is connected. The adapters 70a,..., 70n are connected to the network 30 via the second routers 90a,. 6, amplifiers 61, 71a,..., 71n, microphones 62 and speakers 72a,..., 72n are amplifiers 11, 21a, ..., 21n, microphones 12 and speakers 22a,. .., corresponding to 22n.

In this communication system 1b, since the second routers 90a,..., 90n obtain dynamic IP addresses directly from a DHCP server (not shown), each network adapter 70a,. Note that control according to (Network) is performed. In view of this point, each network adapter 70a,..., 70n performs notification processing for performing notification of a dynamic IP address to a fixed IP address, so that the dynamic IP address is a network adapter as a parent device. 60 is notified. FIG. 6 shows a case where a fixed IP address is assigned to the first router 80 connected to the ISP according to a DHCP server (not shown). 6 shows a case where a dynamic IP address is assigned to the second routers 90a,..., 90n connected to the ISP according to a DHCP server (not shown).
In the following description, similarly to the description of the first embodiment, in the description common to each of the plurality of network adapters 70a,... In the description of the network adapter 60, it is simply referred to as the parent device 60. Furthermore, in the description common to each of the plurality of second routers 90a,..., 90n, each second router is simply referred to as the second router 90.

[Slave unit 70]
FIG. 7 is a block diagram for explaining the function of the slave unit 70.
7 includes a storage unit 401, a first notification unit 402, a monitoring unit 403, a switching unit 404, a second notification unit 405, a notification unit 406, and a stop unit 407. The storage unit 401, the monitoring unit 403, the switching unit 404, the notification unit 406, and the stop unit 407 are the same as the storage unit 301, the monitoring unit 304, the switching unit 306, the notification unit 307, and the stop unit 308 shown in FIG. is there.
Below, the difference of the subunit | mobile_unit 70 of this embodiment from the subunit | mobile_unit 20 of 1st Embodiment is demonstrated.

Unlike the child device 20, the child device 70 is connected to the network 30 via the second router 90, and therefore does not require the acquisition unit 302 (see FIG. 3) for acquiring a dynamic IP address.
Furthermore, the notification process in the first notification unit 402 and the second notification unit 405 is different from the slave device 20 in the notification method.
Specifically, the notification process is performed as follows. That is, the first notification unit 402 and the second notification unit 405 generate a notification message when performing notification processing for performing notification of a dynamic IP address to a fixed IP address, The message is sent to the second router 90. This message is transmitted according to, for example, IEEE 802.3.

  In addition to information indicating the content of the notification, the message for notification includes a fixed IP address and information designating itself. Since the dynamic IP address is set in the packet corresponding to the message in the subsequent processing of the second router 90, the set dynamic IP address can be registered in the parent device 60. .

  6 includes a receiving unit 201, a registration unit 202, a response unit 203, and a management table 2021, similar to the one shown in FIG.

[Operation of communication system]
Hereinafter, the overall operation of the communication system 1b of the present embodiment will be described with reference to FIG.
FIG. 8 is a flowchart showing the overall operation when a dynamic IP address is registered in the parent device 60.
In FIG. 8, first, the slave device 70 (first notification unit 402) periodically performs notification processing (first notification processing) for notifying the parent device 60 of the dynamic IP address via the second router 90. (For example, at intervals of 10 s) (step S201). For this purpose, the first notification unit 402 reads the fixed IP address from the storage unit 401, and in addition to information indicating the content of the notification, the first notification unit 402 sends a message including the fixed IP address and information indicating itself to the second router 90. To the network 30 via. In this example of the overall operation, since the dynamic IP address is assigned to the second router 90, in step S202, the second router 90 sets the dynamic IP address in the packet corresponding to the message from the slave unit 70. Then, the packet (dynamic IP address notification performed based on the notification process) is relayed to the first router 80 via the network 30. As a result, the dynamic IP address is notified to the parent device 60.

  As a result, when the parent device 60 (receiving unit 201) receives the dynamic IP address (notification of dynamic IP address) via the first router 80 (YES in step S203), the parent device 60 (registration). Unit 202) performs registration processing of the dynamic IP address (step S204). An example of this registration process is the same as step S104 in FIG.

  Then, base unit 60 (replying unit 203) performs a reply process corresponding to the notification of the dynamic IP address performed based on the notification process to slave unit 70 via first router 80 (step S205). . For this purpose, the response unit 203 sends a message including the dynamic IP address registered in step S204 and information indicating itself to the network 30 via the first router 80 in addition to the information indicating the content of the response. To do. In this example of the overall operation, since the fixed IP address is assigned to the first router 80, the first router 80 sets the fixed IP address in the packet corresponding to the message from the parent device 60 in step S206. The packet is relayed to the second router 90 via the network 30. As a result, a response in response to the notification of the dynamic IP address is sent to the slave unit 70.

  The slave device 70 (monitoring unit 403) monitors whether or not a response from the master device 60 has been received (step S207), and as a result, if it is determined that no response has been received (NO), The subunit | mobile_unit 70 (2nd notification part 405) performs the notification process (2nd notification process) for performing notification of a dynamic IP address. That is, the second notification unit 405 shortens the time interval of the notification process executed in step S201 (1s in the example of FIG. 8) and executes the notification process (step S208). For this purpose, the second notification unit 405 also reads out the fixed IP address from the storage unit 401, and in addition to information indicating the content of the notification, a message including the fixed IP address and information indicating itself is sent to the second router 90. To the network 30 via. Thereby, the main | base station 60 can register a dynamic IP address rapidly.

  Note that after determining NO in step S207, handset 60 (notification unit 406) may transmit (notify) a message indicating that there is no response to, for example, a personal computer (not shown). Or the subunit | mobile_unit 20 (stop part 407) may stop transmission of the audio | speech data currently transmitting to the main | base station 60, for example.

  In FIG. 8, the process of steps S209 to S210 is the same as the process of steps S108 to S109 of FIG.

  As described above, in the communication system 1b of the present embodiment, each of the plurality of slave units 70 periodically performs notification processing for notifying the master unit 60 of a dynamic IP address, If there is no response from the parent device 60 in response to the notification of the dynamic IP address performed based on the notification processing, the notification processing is changed to a time interval shorter than the time interval for periodically executing the notification processing. Execute. Therefore, in the communication system 1b, as in the first embodiment, when a failure occurs on the parent device 60 side, the dynamic IP address for the parent device 60 to realize connection with each child device 70 is used. Is registered quickly.

<Example of change of embodiment>
The communication system according to each of the above-described embodiments is merely an example, and changes can be made based on this.

The slave unit of each embodiment can be switched to the master unit at a predetermined timing. The predetermined timing is set so that communication between the parent device and the child device can be appropriately performed. For example, it is assumed that the predetermined timing is when a state in which there is no response from the parent device (NO in step S106 in FIG. 4 or NO in step S207 in FIG. 8) continues for a certain period. In this case, the slave unit switches to the master unit after a certain period of time has elapsed (the mode by the program is switched from the slave unit to the master unit) and is assigned a fixed IP address. This fixed IP address is newly set in each slave unit. Next, each child device and the parent device perform dynamic IP address registration processing (a series of processing shown in FIG. 4 or FIG. 8). The predetermined timing described above may be a case where the slave unit receives a command for switching from a computer (not shown) (for example, a server, a personal computer, etc.). In this case, the slave unit can be switched to the master unit based on the command (the mode by the program is switched from the slave unit to the master unit).
In addition, the parent device of each embodiment can also be switched to the child device at a predetermined timing (for example, when a switching command is received from a computer not shown). In that case, the parent device switches to the child device based on the command (the mode by the program is changed from the parent device to the child device).

  As another example of the slave unit of the present invention, any device that can be connected to a network using a dynamic IP address may be used. For example, a personal computer or an exchange may be used. As another example of the parent device of the present invention, any device that can be connected to a network using a fixed IP address may be used. For example, a server, an exchange, or the like may be used.

  In each embodiment, the case where the number of parent devices arranged in the network 30 is one has been described, but a plurality of parent devices may be arranged. In this case, in order to notify the dynamic IP address suitable for the communication environment (communication speed, etc.) of each parent device, the child device determines whether or not to periodically notify each parent device at what time interval. It has a configuration that can be managed at all times. Therefore, for each parent device, the child device described above has a fixed IP address necessary for connection with the parent device, a periodic time interval for performing notification processing for notification of a dynamic IP address, and a parent device. By having a table for managing the longest period during which a response from the machine can be received, the communication system can realize the same operation as the communication system of each embodiment.

10 Network adapter (base unit)
20a, 20n Network adapter (slave unit)
30 network network 201 reception unit 202 registration unit 203 response unit 301 storage unit 302 acquisition unit 303 first notification unit 304 monitoring unit 305 second notification unit 306 switching unit 307 notification unit 308 stop unit 2021 management table

Claims (5)

A communication system comprising a plurality of master units connected to a network using a fixed IP address and a plurality of slave units connected to the network using a dynamic IP address,
Each of the plurality of slave units is
A storage unit that stores in advance a plurality of fixed IP addresses of the plurality of parent devices and a plurality of time intervals determined for each of the parent devices, which are regular time intervals for executing the notification process of the dynamic IP addresses When,
A first notification unit that executes before Symbol the notification process was determined for each of the master unit periodic time intervals to the fixed IP address of the master unit,
A monitoring unit for monitoring whether or not a response transmitted from each of the plurality of master units has been received in response to a notification of a dynamic IP address performed based on the notification process;
If there is no reply from at least one master unit of the plurality of base unit performs a pre-Symbol notification processing the at least one determined for each base unit has the regular time intervals shorter comb respectively A second notification unit;
Have
Each of the plurality of master units is
A receiving unit that receives the notification when there is a notification of a dynamic IP address performed based on the notification processing;
A registration unit for registering the notified dynamic IP address;
A response unit that responds to the slave unit in response to the notification to the registered dynamic IP address;
A communication system characterized by the above. The slave is
If there is no response from the at least one master unit, further has a notification unit that notifies that there is no response,
The communication system according to claim 1. The slave is
When the there is a transmission request for predetermined information from at least one master unit, wherein when there is no reply from at least one base unit further includes a stop portion for stopping the transmission of the predetermined information,
The communication system according to claim 1 or 2. The parent device or child device is configured to be switchable as the child device or the parent device at a predetermined timing.
The communication system according to any one of claims 1 to 3, characterized in that: A plurality of parent devices connected to a network using a fixed IP address and connected via the network, and connected to the network using a dynamic IP address,
A storage unit that stores in advance a plurality of fixed IP addresses of the plurality of parent devices and a plurality of time intervals determined for each of the parent devices, which are regular time intervals for executing the notification process of the dynamic IP addresses When,
A first notifying unit for performing the previous SL the notification process was determined for each of the master unit periodic time intervals to the fixed IP address of the master unit,
A monitoring unit for monitoring whether or not a response transmitted from each of the plurality of master units has been received in response to a notification of a dynamic IP address performed based on the notification process;
Wherein the plurality of if there is no reply from at least one master unit of the base unit, the second performing the notification processing said at least one said regular time intervals determined for each base unit and the short comb respectively A notification unit;
It is provided with the cordless handset.

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