JP2016103774A - Communication control device, server, communication system, and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To restrain increase in cost involved in the update of hardware of a communication control device by locally stopping the update of hardware of the communication control device.SOLUTION: A communication control device has a first function among functions executable for sound data, the first function converting sound data transmitted by a first terminal in a first network into sound data with a data format transferable to a second terminal in a second network different from the first network, and transferring the resultant data to the second terminal. The communication control device receives first information to give an instruction to perform a second function other than the first function from the first terminal, and if its processing unit does not have the second function which the received first information gives the instruction to perform, it transmits second information to give an instruction to perform the second function to a first external apparatus. If the communication device receives third information to indicate the second function can be performed from the first external apparatus, it uses a path used for transferring sound data to the second terminal as a path to transfer sound data to the second terminal via the first external apparatus.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to a communication control device, a server, a communication system, and a communication control method.

  With the next generation IP (Internet Protocol) network technology called NGN (Next Generation Network), there is a movement to replace the current public network with an IP network. Telecommunications carriers are promoting the use of IP and optical communications, and the number of IP telephone subscribers is increasing year by year. Further, as represented by cloud technology, there is an increasing demand for freely distributing communication control devices on an IP network.

JP 2006-033732 A

  However, in a system in which communication control devices are distributed on an IP network, the number of devices becomes enormous, and thus there is a problem that the cost for supporting new functions and updating hardware increases.

  The communication control apparatus according to the embodiment includes a processing unit, a communication unit, and a control unit. The processing unit can transfer the sound data transmitted from the first terminal in the first network to the second terminal in the second network different from the first network among the functions executable for the sound data. It has a first function of converting to a data format and transferring it to the second terminal. The communication unit receives, from the first terminal, first information instructing execution of a second function other than the first function among the functions of the processing unit, and the second function instructed to be executed by the received first information. If the processing unit does not have, the second information instructing execution of the second function is transmitted to the first external device. When the control unit receives the third information indicating that the second function can be executed from the first external device, the control unit transmits the sound data to the second terminal via the first external device. Is a path to be transferred to the second terminal.

FIG. 1 is a diagram illustrating a configuration of a communication system according to the first embodiment. FIG. 2 is a block diagram illustrating a functional configuration of each device included in the communication system according to the first embodiment. FIG. 3 is a diagram illustrating a data configuration of system information and counter apparatus information stored in the management apparatus included in the communication system according to the first embodiment. FIG. 4 is a diagram illustrating a data configuration of DSP management information and voice server management information stored in the management apparatus included in the communication system according to the first embodiment. FIG. 5 is a diagram for explaining path switching processing in the communication system according to the first embodiment. FIG. 6 is a sequence diagram illustrating a flow of path switching processing in the communication system according to the first embodiment. FIG. 7 is a diagram illustrating a configuration of a communication system according to the second embodiment. FIG. 8 is a block diagram illustrating a functional configuration of each device included in the communication system according to the second embodiment. FIG. 9 is a diagram illustrating a data configuration of system information and counter device information stored in the management device included in the communication system according to the second embodiment. FIG. 10 is a diagram illustrating a data configuration of DSP management information and high-function network device management information stored in the management apparatus included in the communication system according to the second embodiment. FIG. 11 is a diagram for explaining path switching processing in the communication system according to the second embodiment. FIG. 12 is a sequence diagram illustrating a flow of path switching processing in the communication system according to the second embodiment.

  Hereinafter, a communication control device, a server, a communication system, and a communication control method according to the present embodiment will be described with reference to the accompanying drawings.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration of a communication system according to the first embodiment. As shown in FIG. 1, the communication system 1 according to the present embodiment includes local terminals LT1, LT2, and LT3 (hereinafter, local terminals LT1, LT2, and LT3, which are examples of terminals). Terminal LT), network devices PS1, PS2, and PS3 (hereinafter, referred to as network devices PS when there is no need to distinguish the network devices PS1, PS2, and PS3), which are examples of communication control devices, and Voice servers S1 and S2 (hereinafter referred to as voice server S when it is not necessary to distinguish between the voice servers S1 and S2), and a management device M, which are examples of servers (or external devices). doing. In the communication system 1 according to the present embodiment, the network device PS, the voice server S, and the management apparatus M are connected via a network NW such as an IP (Internet Protocol) network or a public communication network.

  The local terminal LT is composed of, for example, a PHS (Personal Handy-phone System), a base station, a PBX (Private Branch Exchange), etc., and another local network different from the local network in which the local terminal exists via the network device PS. It is possible to communicate with other local terminals LT.

  The network device PS is configured by a gateway or the like, for example, and is connected to the network NW. The network device PS is connected to a local network where the local terminal LT exists. Then, the network device PS establishes communication between the local terminals LT in different local networks.

  Specifically, the network device PS is a local terminal LT that is an example of a first terminal in a certain local network (an example of a first network) among functions that can be executed on voice data (an example of sound data). Transfer voice data transmitted from (hereinafter referred to as a transmission source device) to a local terminal LT (hereinafter referred to as a counter device), which is an example of a second terminal in another local network (an example of a second network). It has a DSP (Digital Signal Processor) unit 111 that is an example of a processing unit that has a conversion function (an example of a first function) that converts data into a possible data format and transfers it to the opposite device.

  The management apparatus M provides service information indicating system information 104 (see FIG. 2) related to the voice server S, and functions (service functions that are functions that can be executed on voice data) included in the high-function DSP unit 106 of the voice server S. Voice server management information 105 including a list of information (see FIG. 2), opposite device information 300 regarding the network device PS (see FIG. 3), and type of high function DSP unit 106 of the voice server S (hereinafter referred to as DSP type) The DSP management information 400 (see FIG. 4) relating to each function is stored.

  Further, the management apparatus M determines a combination of the voice server S and the network device PS based on the system information 104 and the counter apparatus information 300. Then, the management apparatus M notifies the determined combination to the network device PS. Further, the management apparatus M generates voice server management information 105 (see FIG. 2) including a list of service information that can be provided based on the DSP management information 400. Then, the management apparatus M transmits the generated voice server management information 105 to the voice server S. In the present embodiment, the management apparatus M transmits the voice server management information 105 to the voice server S regardless of whether there is a request from the voice server S. The server management information 105 may be transmitted to the voice server S.

  The voice server S includes a high function DSP unit 106 that is an example of a processing unit. Further, the voice server S relays communication between the network devices PS according to the service request message from the network device PS. At that time, the voice server S can apply the voice mixing service for executing the service function to the voice data exchanged between the network devices PS by controlling the high function DSP unit 106.

  Next, the functional configuration of each device included in the communication system according to the present embodiment will be described with reference to FIGS. FIG. 2 is a block diagram illustrating a functional configuration of each device included in the communication system according to the first embodiment. FIG. 3 is a diagram illustrating a data configuration of system information and counter apparatus information stored in the management apparatus included in the communication system according to the first embodiment. FIG. 4 is a diagram illustrating a data configuration of DSP management information and voice server management information stored in the management apparatus included in the communication system according to the first embodiment.

  As illustrated in FIG. 2, the management apparatus M includes a system information management unit 101, a counter device determination unit 102, and a service management unit 103.

  The system information management unit 101 stores system information 104, voice server management information 105, opposite device information 300 (see FIG. 3), DSP management information 400 (see FIG. 4), and the like. As shown in FIG. 3, the system information 104 is associated with a voice server ID that enables the voice server S in the communication system 1 to be identified, and the type of the high function DSP unit 106 of the voice server S (hereinafter referred to as the DSP type). On-board DSP information indicating the service function of the high-function DSP unit 106 of the voice server S, geographical information indicating the position of the voice server S, and the IP address of the voice server S. Including.

  As shown in FIG. 3, the opposing device information 300 is associated with a network device ID that allows the network device PS to be identified, and includes installed DSP information that can identify the DSP type of the DSP unit 111 included in the network device PS, A connection destination voice server ID that enables identification of a voice server S (hereinafter referred to as a predetermined voice server S) combined with the network device PS, geographical information indicating the location of the network device PS, and an IP address of the network device PS And including.

  As shown in FIG. 4, the DSP management information 400 is provided so that the service function of the high-function DSP unit 106 of the DSP type can be identified in association with the DSP type of the high-function DSP unit 106 of the voice server S. Service information and the serial number of the high-function DSP unit 106 of the DSP type. In the present embodiment, the serial number of the high function DSP unit 106 is used as an example of information that can identify the service function of the high function DSP unit 106 of each voice server S. However, the present invention is not limited to this. For example, the serial number of the voice server S may be information that makes it possible to identify the service function of the high function DSP unit 106 of each voice server S.

  As shown in FIG. 4, the voice server management information 105 is associated with a voice server ID that enables the voice server S to be identified, the DSP type of the high function DSP unit 106 that the voice server S has, service information that can be provided, , The geographical information of each voice server S, the IP address of each voice server S, and the serial number of the high function DSP unit 106 possessed by each voice server S.

  The opposite device determination unit 102 includes the geographical information of the network device PS and the voice server S and the IP of each of the network device PS and the voice server S included in the system information 104 and the opposite device information 300 stored in the system information management unit 101. Based on the address or the like, a network device PS that is a transmission source of voice data to which the voice mixing service is applied is assigned to each voice server S. In other words, the corresponding device determination unit 102 determines a combination of the voice server S and the network device PS based on the system information 104 and the opposite device information 300. Then, the opposing device determination unit 102 notifies the network device PS of the combination of the voice server S and the network device PS.

  Based on the DSP management information 400 stored in the system information management unit 101, the service management unit 103 extracts service information indicating the service function of the high-function DSP unit 106 of the voice server S and can provide the extracted service information. Voice server management information 105 including a list of service information is generated. Then, the service management unit 103 notifies the generated voice server management information 105 to the voice server S.

  As shown in FIG. 2, the voice server S includes a high function DSP unit 106, a message receiving unit 107, a voice path control unit 108, a service selection unit 109, and a voice server management information storage unit 110.

  As described above, the high function DSP unit 106 has a service function. The message receiving unit 107 receives a service request message, which is an example of information instructing execution of a function for voice data, from the network device PS. In the present embodiment, the message receiving unit 107 receives a service request message including information (for example, serviceable service information) that makes it possible to identify a function to be executed from the network device PS. The message receiving unit 107 includes a function that is instructed to be executed by the received service request message (in this embodiment, a function indicated by the service information that can be provided included in the service request message) as a service function that the high function DSP unit 106 has. It is determined whether or not. When the function instructed to be executed by the service request message is included in the service function of the high function DSP unit 106 (when the voice server S can support the function), the message receiving unit 107 instructs to execute by the service request message. A service response message, which is an example of information indicating that the designated function can be executed, is transmitted to the network device PS.

  On the other hand, when the message receiving unit 107 does not have a service function corresponding to the function instructed to be executed by the service request message (when the voice server S cannot support the function), the message receiving unit 107 stores the voice server management information storage unit 110 described later. Based on the stored voice server management information 105, another voice server S (an example of an external server) having a service function corresponding to the function instructed to be executed by the service request message is extracted. Then, the message receiving unit 107 transmits to the network device PS a service response message that is an example of information that makes it possible to identify the extracted other voice server S.

  The voice path control unit 108 controls the high function DSP unit 106 to receive voice data transmitted from the transmission source device (for example, the local terminal LT1) via the network device PS (an example of an external communication control device). . Further, the voice path control unit 108 controls the high function DSP unit 106 to apply the service function (service function selected by the service selection unit 109 described later) to the received voice data by the high function DSP unit 106. And the voice data for which the service function has been executed is transferred to the opposite device (for example, the local terminal LT2).

  The service selection unit 109 selects the function instructed to be executed by the service request message from the service functions of the high function DSP unit 106 as the service function to be executed on the voice data received by the voice path control unit 108. The voice server management information storage unit 110 stores the voice server management information 105 notified from the management apparatus M.

  As illustrated in FIG. 2, the network device PS includes a DSP unit 111, a service determination unit 112, a message transmission unit 113, and a voice path control unit 114. As described above, the DSP unit 111 converts the audio data transmitted from the transmission source device into a data format that can be transferred to the opposite device among the functions executable on the audio data, and transfers the converted data to the opposite device. Function (hereinafter referred to as a conversion function).

  The service determination unit 112 (an example of a communication unit) receives a service request, which is an example of information instructing execution of a function for audio data, from a transmission source device. Then, the service determination unit 112 determines whether the DSP unit 111 has a function that is instructed to be executed by the received service request.

  When it is determined that the DSP unit 111 does not have the function that is instructed to be executed by the service request, the message transmission unit 113 (an example of a communication unit) stores information that instructs execution of the function that is instructed to be executed by the service request. An example service request message is transmitted to a predetermined voice server S. In the present embodiment, the message transmission unit 113 transmits a service request message including information (for example, service information that can be provided) that enables identification of a function instructed to be executed by a service request to a predetermined voice server S. In the present embodiment, the message transmission unit 113 transmits a service request message to a predetermined voice server S, but the voice transmission unit 113 has a high-function DSP unit 106 that has higher functionality than the DSP unit 111 of the network device PS. The present invention is not limited to this as long as it transmits a service request message to the server S. For example, the message transmission unit 113 accesses the voice server management information 105 stored in the management apparatus M via the network NW, and acquires the serial number of the high function DSP unit 106 of the voice server S included in the communication system 1. Among the high-function DSP units 106 specified by the acquired serial number, the high-performance DSP unit 106 having higher functions than the DSP unit 111 (for example, a high function having more service functions than the number of functions of the DSP unit 111) The service request message may be transmitted to the voice server S having the function DSP unit 106 or the like or the voice server S having the high function DSP unit 106 having a function different from that of the DSP unit 111. When the message transmission unit 113 receives a service response message, which is an example of information indicating that the function instructed to be executed by the service request message can be executed from a predetermined voice server S, the message transmission unit 113 sends a message to the voice path control unit 114. And instructing switching to a path for transferring audio data via a predetermined audio server S.

  On the other hand, when the message transmission unit 113 receives a service response message, which is an example of information enabling the other voice server S to be identified, from the voice server S, the service request message is again sent to the other voice server S. Send. Alternatively, when the message transmission unit 113 receives a service response message enabling identification of another voice server S from the voice server S, the message transmission unit 113 sends voice data to the voice path control unit 114 via the other voice server S. It may be instructed to switch to a path for transferring.

  The voice path control unit 114 (an example of a control unit), when instructed by the message transmission unit 113 to switch to a path for transferring voice data via a predetermined voice server S, switches from the transmission source device to the opposite device. A path switching process is performed in which the path used for transferring the audio data is a path for transferring the audio data from the transmission source apparatus to the opposite apparatus via the predetermined audio server S. In this embodiment, when the voice path control unit 114 is instructed to switch to a path for transferring voice data via the predetermined voice server S, the voice data transfer destination by the DSP unit 111 is set to the predetermined voice server S. And a path switching instruction, which is an example of information for notifying the path of voice data via the predetermined voice server S, is transmitted to the network device PS connected to the local network where the opposite apparatus is located. Here, in the path switching process, in addition to the process of switching the path used for transferring the voice data from the transmission source apparatus to the opposite apparatus to the path for transferring the voice data via the predetermined voice server S, the transmission source apparatus When the path used for transferring the audio data from the device to the opposite device is performed via the predetermined audio server S, the path used for transferring the audio data from the transmission source device to the opposite device is maintained. It is also included.

  On the other hand, when the message transmission unit 113 instructs the voice path control unit 114 to switch to a path for transferring voice data via another voice server S, the voice path control unit 114 transfers the voice data from the transmission source device to the opposite device. A path switching process is performed in which the path used for the above is a path for transferring voice data from the transmission source apparatus to the opposite apparatus via another voice server S. In the present embodiment, when the voice path control unit 114 is instructed to switch to a path for transferring voice data via another voice server S, the voice data transfer destination by the DSP unit 111 is set to the other voice server S. Is an example of information for notifying the network device PS connected to the local network in which the opposite device is located of the voice data path through another voice server S that is the voice data transfer destination. A path switching instruction is transmitted.

  Next, the determination process of the combination of the voice server S and the network device PS by the management apparatus M will be described with reference to FIG.

  As described above, a predetermined voice server S that transmits a service request message (that is, a voice server S combined with the network device PS) is set in the network device PS. The network device PS receives a service request from the transmission source device, and transmits a service request message to a predetermined voice server S when its DSP unit 111 does not have a function instructed to be executed by the service request. To do. Further, when the predetermined voice server S does not have a service function corresponding to the function instructed to be executed by the service request received from the transmission source device, the network device PS has a voice server other than the predetermined voice server S. A service request message is transmitted to S again.

  The combination of the voice server S and the network device PS is determined as follows. The opposing device determination unit 102 of the management device M determines a combination of the network device PS and the voice server S based on the system information 104 and the opposing device information 300. For example, when determining the voice server S to be combined with the network device PS having the network device ID “1” stored in the opposing device information 300, the opposing device determination unit 102 uses the network device ID: “1” in the opposing device information 300. Geographic information associated with: “00 city” is identified. Then, the opposing device determination unit 102 is identified in the system information 104 by the voice server ID: “1001” associated with the specified geographic information: “OO city” and the same geographic information: “OO city”. The voice server S to be combined with the network device PS having the network device ID “1” is determined. In addition, in the system information 104, the opposite device determination unit 102 determines that there are a plurality of voice server IDs associated with the identified geographic information: “XX city” and the same geographic information: “XX city”. Of the voice servers S identified by the plurality of voice server IDs, a production number different from the production number of the voice server S having an IP address in the network where the network device PS exists and the DSP unit 111 of the network device PS The voice server S having the high-functional DSP unit 106 is determined as the voice server S to be combined with the network device PS identified by the network device ID: “1”.

  Here, an example has been described in which the opposing device determination unit 102 preferentially uses the geographical information included in the system information 104 and the opposing device information 300 to determine the combination of the network device PS and the voice server S. Without limitation, the combination of the network device PS and the voice server S is determined by preferentially using the IP address included in the system information 104 and the opposite device information 300, the serial numbers of the network device PS and the voice server S, etc. You may do it. Alternatively, the opposing device determination unit 102 determines the combination of the network device PS and the voice server S based on the number of network devices PS combined with each voice server S, thereby causing a load bias between the voice servers S. It is also possible to appropriately set the combination of the network device PS and the voice server S so that no occurrence occurs.

  Next, the notification process of the voice server management information 105 by the management apparatus M and the extraction process of another voice server S by the voice server S will be described with reference to FIG.

  First, the notification process of the voice server management information 105 by the management apparatus M will be described. The service management unit 103 identifies the DSP type of the high function DSP unit 106 included in each voice server S. Next, the service management unit 103 extracts, from the DSP management information 400, the service information that can be provided and the serial number associated with the DSP type of the high function DSP unit 106 included in each voice server S. Then, as shown in FIG. 4, the service management unit 103 includes a voice server ID that enables each voice server S to be identified, a DSP type of the high function DSP unit 106 that each voice server S has, and an extracted service that can be provided The voice server management information 105 that associates the information, the geographic information of each voice server S, the IP address of each voice server S, and the extracted production number is generated.

  Then, the service management unit 103 transmits the generated voice server management information 105 to all the voice servers S in the communication system 1. Thereby, all the voice servers S in the communication system 1 store the same voice server management information 105 in the voice server management information storage unit 110.

  Next, extraction processing of another voice server S by the voice server S will be described. The message receiving unit 107 of the voice server S receives the service request message from the network device PS, and when the function instructed to be executed by the received service request message cannot be supported by the voice server S, the voice server management information Based on the voice server management information 105 stored in the storage unit 110, another voice server S capable of supporting the function instructed to be executed by the received service request message is extracted.

  Specifically, the message receiving unit 107 corresponds to the service service information indicating the service function corresponding to the function instructed to be executed by the received service request message among the voice server IDs included in the voice server management information 105. The voice server ID of the other voice server S attached is extracted.

  In the present embodiment, the message receiving unit 107 extracts another voice server S based on the voice server management information 105 stored in the voice server management information storage unit 110. However, the present invention is not limited to this. The voice server management information 105 stored in the management apparatus M may be acquired via the network NW, and another voice server S may be extracted based on the acquired voice server management information 105.

  Further, in the present embodiment, the message receiving unit 107 uses the provided service function information included in the voice server management information 105 to use a high function DSP unit having a service function corresponding to the function instructed to be executed by the service request message. However, the present invention is not limited to this. For example, based on the serial number of the high function DSP unit 106 of each voice server S included in the voice server management information 105. Another voice server S provided with the high function DSP unit 106 having a service function corresponding to the function instructed to be executed by the service request message may be extracted.

  Then, the message reception unit 107 selects one or more voice server IDs from the extracted voice server ID, and transmits a service response message including the selected voice server ID to the network device PS. When a plurality of voice server IDs having a high function DSP unit 106 having a service function corresponding to the function instructed to be executed by the service request message are extracted, the message receiving unit 107 provides the service included in the voice server management information 105 A service including the voice server ID of the voice server S provided with the lowest-functioning high-function DSP unit 106 among the high-function DSP units 106 included in each extracted voice server S based on the function information (or serial number) or the like Send a response message. As a result, when the voice server S having the high-function high-performance DSP unit 106 is in a state where it can always be used as much as possible and a service request message instructing execution of a higher-function service function is received, the high-function high-performance The voice server S including the function DSP unit 106 can be extracted as another voice server S. Further, the message receiving unit 107 may transmit a service response message including a voice server ID stored in association with the same geographic information as the geographic information of the voice server S itself among the extracted voice server IDs. Thereby, it is possible to prevent the voice server S connected via the plurality of network devices PS from being selected as another voice server S. In addition, the message receiving unit 107 may transmit a service response message including a voice server ID stored in association with an IP address in the network where the voice server S exists, among the extracted voice server IDs. Alternatively, the message receiving unit 107 outputs a service response message including the voice server ID of the voice server S with the smallest load on the high function DSP unit 106 of the voice server S indicated by the voice server ID among the extracted voice server IDs. You may send it. For example, the message receiving unit 107 transmits a service response message including the voice server ID of the voice server S with the smallest number of network devices PS combined by the management apparatus M.

  Next, a path switching process in the communication system 1 according to the present embodiment will be described with reference to FIG. FIG. 5 is a diagram for explaining path switching processing in the communication system according to the first embodiment. Here, the path switching process in the case of transmitting voice data from the local terminal LT1 of the transmission source apparatus to the local terminal LT2 of the opposite apparatus will be described, but in the case of transmitting and receiving voice data between other local terminals LT The path switching process is performed in the same manner.

  The service determination unit 112 of the network device PS1 is in a state where communication is established between the local terminal LT1 and the local terminal LT2 (that is, in a state where voice data is transmitted / received between the local terminals LT1 and LT2). When a service request is received from the local terminal LT1 (step S501), it is determined whether the DSP unit 111 has a function instructed to be executed by the received service request. When the message transmission unit 113 of the network device PS1 determines that the DSP unit 111 does not have a function that is instructed to be executed by the received service request, the message transmission unit 113 instructs to execute the function that is instructed to be executed by the received service request. The service request message to be transmitted is transmitted to a predetermined voice server S1 (step S502). Thereafter, when the message transmitting unit 113 receives a service response message indicating that the function instructed to be executed by the service request message can be executed from the voice server S1 (step S502), the voice path control unit of the network device PS1 114 is instructed to switch the path used for transferring the audio data.

  When the message transmission unit 113 instructs the voice path control unit 114 to switch the path used for transferring voice data, the voice path control unit 114 sets the path used for transferring voice data from the local terminal LT1 to the local terminal LT2 via the voice server S1. Then, a path switching process is performed for a path for transferring audio data from the local terminal LT1 to the local terminal LT2. Specifically, the voice path control unit 114 transmits a path switching instruction for notifying the voice data path via the voice server S1 to the network device PS2 connected to the local network where the local terminal LT2 exists. (Step S503). Further, the voice path control unit 114 transmits a path switching instruction to the network device PS2, and then sets the voice server S1 as the voice data transfer destination by the DSP unit 111 of the network device PS1 (step S504). This prevents the transfer destination of the voice data from being switched to the voice server S1 before transmitting the path switching instruction to the network device PS2, and prevents the network device PS2 from receiving voice data from the voice server S1. To do.

  The voice path control unit 108 of the voice server S1 controls the high function DSP unit 106 to receive voice data transmitted from the local terminal LT1 via the network device PS1. Then, the voice path control unit 108 controls the high function DSP unit 106 to apply the voice mixing service to the received voice data (step S505). Specifically, the high function DSP unit 106 performs voice mixing on the received voice data by executing a service function (for example, a conference function or an announcement synthesis function) instructed to be executed by a service request message. Apply service. Thereafter, the voice path control unit 108 controls the high function DSP unit 106 to transfer the voice data to which the voice mixing service is applied to the network device PS2.

  Thus, even if the network device PS1 does not have the function that is instructed to be executed by the service request message received from the local terminal LT1, the voice data that has executed the function is stored in the local terminal LT2. Therefore, the hardware update of the network device PS1 can be locally suppressed, and the increase in cost associated with the hardware update of the network device PS1 can be suppressed.

  Next, a flow of path switching processing in the communication system 1 according to the present embodiment will be described with reference to FIG. FIG. 6 is a sequence diagram illustrating a flow of path switching processing in the communication system according to the first embodiment. Here, the path switching process in the case of transmitting voice data from the local terminal LT1 of the transmission source apparatus to the local terminal LT2 of the opposite apparatus will be described, but in the case of transmitting and receiving voice data between other local terminals LT The path switching process is performed in the same manner.

  The local terminal LT1 determines a voice path which is a path used for transmission / reception of voice data with the network device PS1 connected to the local network in which the local terminal LT1 exists (step S601). Further, the local terminal LT2 determines a voice path used for transmission / reception of voice data to / from the network device PS2 connected to the local network where the local terminal LT2 exists (step S601). Further, the network device PS1 determines an audio path that is a path used for transferring audio data to the network device PS2 (step S601).

  Thereafter, upon receiving a service request from the local terminal LT1 (step S602), the service determination unit 112 of the network device PS1 determines whether the DSP unit 111 has a function instructed to be executed by the received service request. To do. When it is determined that the DSP unit 111 has a function that is instructed to be executed by the received service request, the DSP unit 111 adds a service request to the voice data received from the local terminal LT1 in addition to the conversion function. The function instructed to be executed by is executed. On the other hand, if the message transmission unit 113 determines that the DSP unit 111 does not have the function that is instructed to be executed by the received service request, the message transmission unit 113 instructs to execute the function that is instructed to be executed by the received service request. A request message is transmitted to a predetermined voice server S1 (step S603).

  When the message receiving unit 107 of the voice server S1 receives the service request message from the network device PS1, whether or not the function instructed to be executed by the service request message is included in the service function of the high function DSP unit 106. A service determination process is performed to determine (step S604).

  If it is determined by the service determination process that the function instructed to be executed by the service request message is included in the service function of the high function DSP unit 106 and the service can be provided (step S605), the message is received. The unit 107 transmits a service response message indicating that the function instructed to be executed by the service request message can be executed to the network device PS1 (step S606).

  When the voice path control unit 114 of the network device PS1 receives a service response message indicating that the function instructed to be executed by the service request message can be executed from the voice server S1, the voice path control unit 114 sends voice data to the network device PS2. A path switching instruction for notifying a path through a predetermined voice server S1 as a transfer destination is transmitted (step S607). Thereafter, the voice path control unit 114 of the network device PS1 sets the transfer destination of the voice data from the local terminal LT1 to the local terminal LT2 in the voice server S1, so that the voice data from the local terminal LT1 to the local terminal LT2 is set. The path used for transfer is switched (step S608).

  Furthermore, the voice path control unit 108 of the voice server S1 controls the high function DSP unit 106 to receive voice data transmitted from the local terminal LT1 via the network device PS1. Then, the voice path control unit 108 controls the high function DSP unit 106 to apply the voice mixing service to the received voice data (step S609). Further, the voice path control unit 108 controls the high function DSP unit 106 to transfer the voice data to which the voice mixing service is applied to the network device PS2.

  On the other hand, when the service determination process determines that the function instructed to be executed by the service request message is not included in the service function of the high function DSP unit 106 and cannot be provided (step S610). Based on the voice server management information 105, the message receiving unit 107 of the voice server S1 extracts another voice server S2 that can support the function instructed to be executed by the received service request message. Then, the message receiving unit 107 transmits a service substitution request instructing execution of the function instructed to be executed by the service request message to the extracted voice server S2 (step S611).

  When the message receiving unit 107 of the voice server S2 determines that the function instructed to be executed by the service replacement request is included in the service function of the high function DSP unit 106 of the voice server S2, the message receiving unit 107 executes the service replacement request. Is transmitted to the voice server S1 indicating that the function instructed can be executed (step S612). On the other hand, if the message receiving unit 107 of the voice server S2 determines that the function instructed to be executed by the service replacement request is not included in the service function of the high function DSP unit 106 of the voice server S2, the message receiving unit 107 responds to the service replacement request. A service alternative response indicating that the function instructed to be executed cannot be executed is transmitted to the voice server S1 (step S612).

  When the service substitute response received from the voice server S2 indicates that the voice server S2 cannot execute the function, the message receiving unit 107 of the voice server S1 Send a service replacement request. On the other hand, if the service substitution response received from the voice server S2 indicates that the voice server S2 can execute the function, the message receiving unit 107 of the voice server S1 includes the voice server ID of the voice server S2. A response message is transmitted to the network device PS1 (step S613).

  When the voice path control unit 114 of the network device PS1 receives a service response message including the voice server ID of the voice server S2 from the voice server S1, the voice data is transmitted via the other voice server S2 to which the voice data is transferred. A path switching instruction for notifying the path is transmitted (step S614). Thereafter, the voice path control unit 114 of the network device PS1 sets the transfer destination of the voice data from the local terminal LT1 to the local terminal LT2 in the voice server S2, so that the voice data from the local terminal LT1 to the local terminal LT2 is set. The path used for transfer is switched (step S615).

  Thereafter, the voice path control unit 108 of the voice server S2 controls the high function DSP unit 106 to receive voice data transmitted from the local terminal LT1 via the network device PS1. Then, the voice path control unit 108 controls the high function DSP unit 106 to apply the voice mixing service to the received voice data (step S616). Then, the voice path control unit 108 controls the high function DSP unit 106 to transfer the voice data to which the voice mixing service is applied to the network device PS2.

  As described above, according to the communication system 1 of the first embodiment, it is possible to locally suppress the hardware update of the network device PS, and to suppress an increase in cost due to the hardware update of the network device PS. .

(Second Embodiment)
In the present embodiment, when the DSP unit of the network device does not have the function instructed to be executed by the service request received from the transmission source device, the path used for transferring the voice data from the transmission source device to the opposite device is This is an example of a path for transferring audio data from the transmission source device to the opposite device via another network device. In the following description, description of the same parts as those in the first embodiment is omitted.

  FIG. 7 is a diagram illustrating a configuration of a communication system according to the second embodiment. As shown in FIG. 7, the communication system 2 according to the present embodiment does not need to distinguish between the local terminal LT, the network device PS, and the high-function network devices HPS1 and HPS2 (hereinafter, high-function network devices HPS1 and HPS2). In this case, it is described as a highly functional network device HPS) and a management apparatus M1. In the communication system 2 according to this embodiment, the network device PS, the high-function network device HPS, and the management apparatus M1 are connected via a network NW such as an IP network or a public communication network.

  The management apparatus M1 determines a combination of the high-function network device HPS and the network device PS based on the system information 204 (see FIG. 8) and the counter apparatus information 900 (see FIG. 9). Then, the management apparatus M1 notifies the determined combination to the network device PS. Further, the management apparatus M1 includes a high-function network device management including a list of service information that can be provided indicating the service functions of the high-function DSP unit 206 of the high-function network device HPS based on the DSP management information 1000 (see FIG. 10). Information 205 (see FIG. 8) is generated. Then, the management apparatus M1 transmits the generated high function network device management information 205 to the high function network device HPS.

  The high-function network device HPS is configured by, for example, a gateway or the like and connected to the network NW, like the network device PS. The high function network device HPS is connected to a local network where the local terminal LT exists. Further, the high function network device HPS establishes communication between the local terminals LT in different local networks. The high function network device HPS has a high function DSP unit 206 having a conversion function and a service function.

  Further, the high-function network device HPS relays communication between the network devices PS according to a service request message from the network device PS. At that time, the high-function network device HPS can apply the voice mixing service for executing the service function to the voice data exchanged between the network devices PS by controlling the high-function DSP unit 206.

  Next, the functional configuration of each apparatus having the communication system according to the present embodiment will be described with reference to FIGS. FIG. 8 is a block diagram illustrating a functional configuration of each device included in the communication system according to the second embodiment. FIG. 9 is a diagram illustrating a data configuration of system information and counter device information stored in the management device included in the communication system according to the second embodiment. FIG. 10 is a diagram illustrating a data configuration of DSP management information and high-function network device management information stored in the management apparatus included in the communication system according to the second embodiment.

  As shown in FIG. 8, the management apparatus M1 includes a system information management unit 201, a counter device determination unit 202, and a service management unit 203.

  The system information management unit 201 stores system information 204, high-function network device management information 205, counter device information 900 (see FIG. 9), DSP management information 1000 (see FIG. 10), and the like.

  As shown in FIG. 9, the system information 204 is associated with a high-function network device ID that enables identification of the high-function network device HPS in the communication system 2, and the DSP of the high-function DSP unit 206 of the high-function network device HPS. On-board DSP information that indicates the type, service information that can be provided that indicates the service function of the high function DSP unit 206 of the high function network device HPS, geographical information that indicates the location of the high function network device HPS, and the high function network device HPS IP address.

  As shown in FIG. 9, the opposing device information 900 is associated with a network device ID that allows the network device PS to be identified, and mounted DSP information that can identify the DSP type of the DSP unit 111 included in the network device PS, A high-function network device HPS that can identify a high-function network device HPS combined with the network device PS (hereinafter referred to as a predetermined high-function network device HPS), geographical information indicating the location of the network device PS, IP address of the network device PS.

  As shown in FIG. 10, the DSP management information 1000 can identify the service function of the high function DSP unit 206 of the DSP type in association with the DSP type of the high function DSP unit 206 of the high function network device HPS. Service information to be provided, and the serial number of the high-function DSP unit 206 of the DSP type. In the present embodiment, the serial number of the high function DSP unit 206 is used as an example of information that can identify the service function of the high function DSP unit 206 of each high function network device HPS. However, the present invention is not limited to this. Instead, for example, the serial number of the high function DSP network server HPS may be information that can identify the service function of the high function DSP unit 206 of each high function network device HPS.

  As shown in FIG. 10, the high-function network device management information 205 is associated with a high-function network device ID that enables identification of the high-function network device HPS, and the DSP of the high-function DSP unit 206 included in the high-function network device HPS. The type, the service information that can be provided, the geographical information of each high-function network device HPS, the IP address of each high-function network device HPS, and the serial number of the high-performance DSP unit 206 that each high-function network device HPS has Including.

  The opposite device determination unit 202 includes the geographical information of each of the network device PS and the high function network device HPS, the network device PS, and the high function network device included in the system information 204 and the opposite device information 900 stored in the system information management unit 201. Based on the IP address or the like of each HPS, a network device PS that is a transmission source of voice data to which the voice mixing service is applied is assigned to each high-function network device HPS. Thereby, the corresponding device determining unit 202 determines a combination of the high-function network device HPS and the network device PS based on the system information 204 and the counter device information 900. Then, the opposing device determination unit 202 notifies the network device PS of the combination of the high function network device HPS and the network device PS.

  Based on the DSP management information 1000 stored in the system information management unit 201, the service management unit 203 extracts and provides the service information that can be provided indicating the service function of the high function DSP unit 206 of the high function network device HPS. High-function network device management information 205 including a list of service information that can be provided is generated. Then, the service management unit 203 notifies the high function network device HPS of the generated high function network device management information 205.

  As shown in FIG. 8, the high function network device HPS includes a high function DSP unit 206, a message reception unit 207, a voice path control unit 208, a service selection unit 209, and a high function network device management information storage unit 210. Have.

  As described above, the high function DSP unit 206 has a conversion function and a service function. The message receiving unit 207 receives a service request message, which is an example of information instructing execution of a function for voice data, from the network device PS. In the present embodiment, the message receiving unit 207 receives a service request message including information (for example, service information that can be provided) that makes it possible to identify a function to be executed from the network device PS. The message receiving unit 207 includes a function instructed to be executed by the received service request message (in this embodiment, the function indicated by the service information that can be provided included in the service request message) in the service function of the high function DSP unit 206. It is determined whether or not. When the function instructed to be executed by the service request message is included in the service function of the high function DSP unit 206 (when it can be supported by the high function network device HPS), the message receiving unit 207 executes by the service request message. Is transmitted to the network device PS as a service response message, which is an example of information indicating that the designated function can be executed.

  On the other hand, when the message receiving unit 207 does not have a service function corresponding to the function instructed to be executed by the service request message (when it cannot be supported by the high-function network device HPS), the high-function network device management information described later Based on the high function network device management information 205 stored in the storage unit 210, another high function network device HPS having a service function corresponding to the function instructed to be executed by the service request message is extracted. Then, the message receiving unit 207 transmits a service response message, which is an example of information that makes it possible to identify the extracted other high-function network device HPS, to the network device PS.

  The voice path control unit 208 controls the high function DSP unit 206 to receive voice data transmitted from the transmission source device via the network device PS (an example of an external communication control device). Further, the voice path control unit 208 controls the high function DSP unit 206 to apply a service function (service function selected by the service selection unit 209 described later) to the received voice data by the high function DSP unit 206. And the voice data for which the service function has been executed is transferred to the opposite device.

  The service selection unit 209 selects the function instructed to be executed by the service request message from the service functions of the high function DSP unit 206 as the service function to be executed on the voice data received by the voice path control unit 208. The high function network device management information storage unit 210 stores high function network device management information notified from the management apparatus M1.

  As shown in FIG. 8, the network device PS includes a DSP unit 111, a service determination unit 112, a message transmission unit 213, and a voice path control unit 214.

  When the DSP unit 111 does not have a function that is instructed to be executed by the service request, the message transmission unit 213 receives a service request message that is an example of information that instructs execution of the function instructed to be executed by the service request. To the advanced network device HPS. In the present embodiment, the message transmission unit 213 transmits a service request message including information (for example, service information that can be provided) that can identify the function instructed to be executed by the service request to a predetermined high-function network device HPS. . When the message transmission unit 213 receives a service response message that is an example of information indicating that the function instructed to be executed by the service request message can be executed from a predetermined high-function network device HPS, the voice path control unit 214 Is instructed to switch to a path for transferring audio data via a predetermined high-function network device HPS.

  On the other hand, when the message transmission unit 213 receives a service response message, which is an example of information enabling identification of another high function network device HPS, from the high function network device HPS, The service request message is transmitted again. Alternatively, when the message transmission unit 213 receives a service response message that makes it possible to identify another high function network device HPS from the high function network device HPS, the message transmission unit 213 sends another high function network device to the voice path control unit 214. You may instruct | indicate the switch to the path | route which transfers audio | voice data via HPS.

  When the message transmission unit 213 instructs the voice path control unit 214 to switch to a path for transferring voice data via a predetermined high-function network device HPS, the voice path control unit 214 transfers the voice data from the transmission source device to the opposite device. A path switching process is performed in which the path used for the transmission is a path for transferring audio data from the transmission source apparatus to the opposite apparatus via a predetermined high-function network device HPS. In this embodiment, when the voice path control unit 214 is instructed to switch to a path for transferring voice data via a predetermined high function network device HPS, the voice path transfer destination by the DSP unit 111 is set to a predetermined high level. The network device PS set to the functional network device HPS and connected to the local network where the opposite device is located is notified of the path of the audio data via the predetermined high-function network device HPS to which the audio data is transferred. The path switching instruction to be transmitted is transmitted.

  On the other hand, when the voice path control unit 214 is instructed by the message transmission unit 213 to switch to a path for transferring voice data via another high-function network device HPS, the voice path control unit 214 sends voice data from the transmission source device to the opposite device. A path switching process is performed in which the path used for the transfer of the voice data is transferred from the transmission source apparatus to the opposite apparatus via another high-function network device HPS. In the present embodiment, when the voice path control unit 214 is instructed to switch to a path for transferring voice data via another high-function network device HPS, the voice path control unit 214 changes the destination of voice data transfer by the DSP unit 111 to another high-level network device HPS. Path switching that is set in the functional network device HPS and notifies the network device PS connected to the local network where the opposite device is located of the other high-function network device HPS that is the transfer destination of the voice data Send instructions.

  Next, a process for determining the combination of the high-function network device HPS and the network device PS by the management apparatus M1 will be described with reference to FIG.

  As described above, a predetermined high-function network device HPS that transmits a service request message (that is, a high-function network device HPS combined with the network device PS) is set in the network device PS. When the network device PS receives a service request from the transmission source device and the DSP unit 111 does not have the function instructed to execute by the service request, the network device PS sends a service request message to a predetermined high-function network device HPS. Send. In addition, when the predetermined high-function network device HPS does not have a service function corresponding to the function instructed to be executed by the service request received from the transmission source device, the network device PS other than the predetermined high-function network device HPS The service request message is transmitted again to the other high-function network device HPS.

  The combination of the high function network device HPS and the network device PS is determined as follows. The opposing device determination unit 202 of the management device M1 determines a combination of the network device PS and the high-function network device HPS based on the system information 204 and the opposing device information 900. For example, when determining the high-function network device HPS to be combined with the network device PS having the network device ID “1” stored in the opposing device information 900, the opposing device determination unit 202 uses the network device ID: “ Geographic information associated with “1”: “00 city” is specified. Then, in the system information 204, the opposite device determination unit 202 uses the high-function network device ID: “50” associated with the identified geographic information: “OO city” identical to the identified geographic information: “OO city”. The high function network device HPS to be identified is determined to be the high function network device HPS combined with the network device PS of the network device ID: [1]. In addition, in the system information 204, the opposing device determination unit 202 has a plurality of high-function network device IDs associated with the specified geographic information: “XX city” and the same geographic information: “XX city”. Includes a high-function network device HPS having an IP address in the network in which the network device PS exists, among the high-function network devices HPS specified by the plurality of high-function network device IDs, and a DSP unit included in the network device PS The high-function network device HPS having the high-function DSP unit 206 having a serial number different from the serial number 111 is determined as the high-function network device HPS combined with the network device PS identified by the network device ID: “1”.

  Here, an example has been described in which the opposite device determination unit 202 determines the combination of the network device PS and the high-function network device HPS using the geographic information stored in the system information 204 and the opposite device information 900. Without limitation, the network device PS and the high-function network device are preferentially used by using the IP address, the network device PS, and the serial numbers of the high-function network devices HPS stored in the system information 204 and the counter device information 900, respectively. A combination of HPS may be determined. Alternatively, the opposing device determining unit 202 determines the combination of the network device PS and the high-function network device HPS based on the number of network devices PS combined with each high-function network device HPS. It is also possible to appropriately set the combination of the network device PS and the high-function network device HPS so as not to cause a load bias between the HPSs.

  Next, with reference to FIG. 10, a description will be given of a process for notifying high-function network device management information by the management apparatus M1 and a process for extracting another high-function network device HPS by the high-function network device HPS.

  First, the notification process of the high-function network device management information 205 by the management apparatus M1 will be described. The service management unit 203 identifies the DSP type of the high function DSP unit 206 included in each high function network device HPS. Next, the service management unit 203 extracts, from the DSP management information 1000, the service information that can be provided and the serial number associated with the DSP type of the high function DSP unit 206 included in each high function network device HPS. Then, as illustrated in FIG. 10, the service management unit 203 identifies the high-function network device ID that enables each high-function network device HPS to be identified and the high-function DSP unit 206 included in each high-function network device HPS. Generate high-function network device management information 205 that associates the type, extracted service information that can be provided, geographic information of each high-function network device HPS, IP address of each high-function network device HPS, and the extracted serial number To do.

  Then, the opposing device determination unit 202 transmits the generated high function network device management information 205 to all the high function network devices HPS in the communication system 2. As a result, all the high-function network devices HPS in the communication system 2 store the same high-function network device management information 205 in the high-function network device management information storage unit 210.

  Next, extraction processing of another high-function network device HPS by the high-function network device HPS will be described. When the message receiving unit 207 of the high function network device HPS receives a service request message from the network device PS and the function instructed to be executed by the received service request message cannot be supported by the high function network device HPS, Based on the high function network device management information 205 stored in the high function network device management information storage unit 210, another high function network device HPS capable of supporting the function instructed to be executed by the received service request message is extracted. .

  Specifically, the message receiving unit 207 can provide a service function corresponding to the function instructed to be executed by the received service request message among the high function network device IDs included in the high function network device management information 205. The high function network device ID of another high function network device HPS associated with the service information is extracted.

  Then, the message reception unit 207 selects one or more high-function network device IDs from the extracted high-function network device ID, and transmits a service response message including the selected high-function network device ID to the network device PS. When a plurality of high function network device IDs having the high function DSP unit 206 having a service function corresponding to the function instructed to be executed by the service request message are extracted, the message receiving unit 207 extracts the high function network device management information 205. High-function network device provided with the lowest-functioning high-function DSP unit 206 among the high-function DSP units 206 included in each high-function network device HPS extracted based on the provided service function information (or serial number) included A service response message including the high-function network device ID of HPS is transmitted. As a result, when a high-function network device HPS provided with a high-function high-performance DSP unit 206 can be used as much as possible and a service request message instructing execution of a higher-function service function is received, A high-function network device HPS having a high-performance DSP unit 106 can be extracted as another high-function network device HPS. Further, the message receiving unit 207 receives a service response message including the high-function network device ID stored in association with the same geographical information as the geographical information of the high-function network device HPS among the extracted high-function network device IDs. You may send it. Thereby, it is possible to prevent a high-function network device HPS connected via a plurality of network devices PS from being selected as another high-function network device HPS. In addition, the message reception unit 207 receives a service response message including the high-function network device ID stored in association with the IP address in the network where the high-function network device HPS exists among the extracted high-function network device IDs. You may send it. Alternatively, the message receiving unit 207 may, among the extracted high-function network device IDs, the high-function network device HPS with the smallest load on the high-function DSP unit 206 of the high-function network device HPS indicated by the high-function network device ID. A service response message including the function network device ID is transmitted. For example, the message receiving unit 207 transmits a service response message including the high-function network device ID of the high-function network device HPS having the smallest number of network devices PS combined by the management apparatus M1.

  Next, the path switching process in the communication system 2 according to the present embodiment will be described with reference to FIG. FIG. 11 is a diagram for explaining path switching processing in the communication system according to the second embodiment. Here, the path switching process in the case of transmitting voice data from the local terminal LT1 of the transmission source apparatus to the local terminal LT2 of the opposite apparatus will be described, but in the case of transmitting and receiving voice data between other local terminals LT The path switching process is performed in the same manner.

  The service determination unit 112 of the network device PS1 is in a state where communication is established between the local terminal LT1 and the local terminal LT2 (that is, in a state where voice data is transmitted / received between the local terminals LT1 and LT2). When a service request is received from the local terminal LT1 (step S1101), it is determined whether the DSP unit 111 has a function that is instructed to be executed by the received service request. If the message transmission unit 213 of the network device PS1 determines that the DSP unit 111 does not have the function instructed to be executed by the received service request, the message transmission unit 213 instructs to execute the function instructed to be executed by the received service request. The service request message to be transmitted is transmitted to the predetermined high function network device HPS1 (step S1102). After that, when the message transmission unit 213 receives a service response message indicating that the function instructed to be executed by the service request message can be executed from the high function network device HPS1 (step S1102), the voice path of the network device PS1 The control unit 214 is instructed to switch the path used for transferring audio data.

  When the message transmission unit 213 instructs the voice path control unit 214 to switch the path used for transferring voice data, the voice path control unit 214 sets the path used for transferring voice data from the local terminal LT1 to the local terminal LT2 to the high-function network device HPS1. A path switching process is performed as a path for transferring audio data from the local terminal LT1 to the local terminal LT2. Specifically, the voice path control unit 214 issues a path switching instruction for notifying the network device PS2 connected to the local network where the local terminal LT2 exists, of the voice data path via the high-function network device HPS1. Transmit (step S1103). Further, after transmitting the path switching instruction to the network device PS2, the voice path control unit 214 sets the voice data transfer destination by the DSP unit 111 of the network device PS1 to the high function network device HPS1 (step S1104). As a result, the voice data transfer destination is switched to the high function network device HPS1 before the path switching instruction is transmitted to the network device PS2, and the network device PS2 can receive the voice data from the high function network device HPS1. Prevent disappearance.

  The voice path control unit 208 of the high function network device HPS1 controls the high function DSP unit 206 to receive the voice data transmitted from the local terminal LT1 via the network device PS1. Then, the voice path control unit 208 controls the high function DSP unit 206 to apply the voice mixing service to the received voice data (step S1105). Specifically, the high function DSP unit 206 performs voice mixing on the received voice data by executing a service function (for example, a conference function, an announcement synthesis function, or the like) instructed to be executed by a service request message. Apply service. Thereafter, the voice path control unit 208 controls the high function DSP unit 206 to transfer the voice data to which the voice mixing service is applied to the network device PS2.

  Thus, even if the network device PS1 does not have the function that is instructed to be executed by the service request message received from the local terminal LT1, the voice data that has executed the function is stored in the local terminal LT2. Therefore, the hardware update of the network device PS1 can be locally suppressed, and the increase in cost associated with the hardware update of the network device PS1 can be suppressed.

  Next, a flow of path switching processing in the communication system 2 according to the present embodiment will be described with reference to FIG. FIG. 12 is a sequence diagram illustrating a flow of path switching processing in the communication system according to the second embodiment. Here, the path switching process in the case of transmitting voice data from the local terminal LT1 of the transmission source apparatus to the local terminal LT2 of the opposite apparatus will be described, but in the case of transmitting and receiving voice data between other local terminals LT The path switching process is performed in the same manner.

  The local terminal LT1 determines a voice path which is a path used for transmission / reception of voice data with the network device PS1 connected to the local network in which the local terminal LT1 exists (step S1201). Further, the local terminal LT2 determines a voice path used for transmission / reception of voice data with the network device PS2 connected to the local network in which the local terminal LT2 exists (step S1201). Further, the network device PS1 determines an audio path that is a path used for transferring audio data to the network device PS2 (step S1201).

  Thereafter, when the service determination unit 112 of the network device PS1 receives a service request from the local terminal LT1 (step S1202), the service determination unit 112 determines whether the DSP unit 111 has a function instructed to be executed by the received service request. To do. When it is determined that the DSP unit 111 has a function that is instructed to be executed by the received service request, the DSP unit 111 adds a service request to the voice data received from the local terminal LT1 in addition to the conversion function. The function instructed to be executed by is executed. On the other hand, when the message transmission unit 213 determines that the DSP unit 111 does not have a function that is instructed to be executed by the received service request, the message transmission unit 213 instructs to execute the function that is instructed to be executed by the received service request. A request message is transmitted to a predetermined high-function network device HPS1 (step S1203).

  When the message receiving unit 207 of the high function network device HPS1 receives the service request message from the network device PS1, whether the function instructed to be executed by the service request message is included in the service function of the high function DSP unit 206. A service determination process is performed to determine whether or not (step S1204).

  Here, when it is determined by the service determination process that the function instructed to be executed by the service request message is included in the service function of the high function DSP unit 206 and the service can be provided (step S1205), the message is received. The unit 207 transmits a service response message indicating that the function instructed to be executed by the service request message can be executed to the network device PS1 (step S1206).

  When the voice path control unit 214 of the network device PS1 receives a service response message indicating that the function instructed to be executed by the service request message can be executed from the high-function network device HPS1, A path switching instruction for notifying a predetermined high-function network device HPS1 that is a transfer destination of audio data is transmitted (step S1207). Thereafter, the voice path control unit 214 sets the transfer destination of the voice data from the local terminal LT1 to the local terminal LT2 to the high function network device HPS1, thereby transferring the voice data from the local terminal LT1 to the local terminal LT2. The path to be used is switched (step S1208).

  Further, the voice path control unit 208 of the high function network device HPS1 controls the high function DSP unit 206 to receive the voice data transmitted from the local terminal LT1 via the network device PS1. Then, the high function DSP unit 206 applies the voice mixing service to the received voice data (step S1209). Furthermore, the voice path control unit 208 controls the high function DSP unit 206 to transfer the voice data to which the voice mixing service is applied to the network device PS2.

  On the other hand, when it is determined by the service determination process that the function instructed to be executed by the service request message is not included in the service function of the high function DSP unit 206 and the service cannot be provided (step S1210). Based on the high-function network device management information 205, the message reception unit 207 of the high-function network device HPS1 extracts another high-function network device HPS2 that can support the function instructed to be executed by the received service request message. Then, the message receiving unit 207 transmits a service substitution request instructing execution of the function instructed to be executed by the service request message to the extracted high function network device HPS2 (step S1211).

  When the message reception unit 207 of the high function network device HPS2 determines that the function instructed to be executed by the service replacement request is included in the service function of the high function DSP unit 206 of the high function network device HPS2, A service replacement response indicating that the function instructed to be executed by the replacement request can be executed is transmitted to the high function network device HPS1 (step S1212). On the other hand, when the message receiving unit 207 of the high function network device HPS2 determines that the function instructed to be executed by the service replacement request is not included in the service function of the high function DSP unit 206 of the high function network device HPS2, A service replacement response indicating that the function instructed to be executed by the service replacement request cannot be executed is transmitted to the high function network device HPS1 (step S1212).

  The message reception unit 207 of the high-function network device HPS1 extracts another high-value when the service replacement response received from the high-function network device HPS2 indicates that the high-function network device HPS2 cannot execute the function. A service replacement request is transmitted to the functional network device HPS. On the other hand, if the message replacement unit 207 of the high function network device HPS1 indicates that the service replacement response received from the high function network device HPS2 indicates that the high function network device HPS2 can execute the function, the high function network device HPS1 A service response message including the high-function network device ID of HPS2 is transmitted to the network device PS1 (step S1213).

  When the voice path control unit 214 of the network device PS1 receives a service response message including the high-function network device ID of the high-function network device HPS2 from the high-function network device HPS1, the other high-function that becomes the transfer destination of the voice data A path switching instruction for notifying the path via the network device HPS2 is transmitted (step S1214). Thereafter, the voice path control unit 214 of the network device PS1 sets the voice data transfer destination from the local terminal LT1 to the local terminal LT2 to the high-function network device HPS2, so that the voice from the local terminal LT1 to the local terminal LT2 is set. The path used for data transfer is switched (step S1215).

  Thereafter, the voice path control unit 208 of the high function network device HPS2 controls the high function DSP unit 206 to receive the voice data transmitted from the local terminal LT1 via the network device PS1. Then, the voice path control unit 208 controls the high function DSP unit 206 to apply the voice mixing service to the received voice data (step S1216). Then, the voice path control unit 208 controls the high function DSP unit 206 to transfer the voice data to which the voice mixing service is applied to the network device PS2.

  Thus, according to the communication system 1 of 2nd Embodiment, the effect similar to 1st Embodiment can be acquired.

  As described above, according to the first and second embodiments, the update of the hardware of the network device PS can be suppressed locally, and the increase in cost associated with the update of the hardware of the network device PS can be suppressed.

  Note that the programs executed by the management apparatuses M and M1, the voice server S, the network device PS, and the high-function network device HPS of the present embodiment are provided by being incorporated in advance in a ROM (Read Only Memory) or the like.

  The programs executed by the management apparatuses M and M1, the voice server S, the network device PS, and the high-function network device HPS according to the present embodiment are files that can be installed or can be executed in a CD-ROM, a flexible disk (FD). ), A CD-R, a DVD (Digital Versatile Disk), or other computer-readable recording medium.

  Furthermore, the programs executed by the management apparatuses M and M1, the voice server S, the network device PS, and the high-function network device HPS of the present embodiment are stored on a computer connected to a network such as the Internet and downloaded via the network. You may comprise so that it may provide. In addition, the program executed by the management apparatuses M and M1, the voice server S, the network device PS, and the high-function network device HPS of the present embodiment may be configured to be provided or distributed via a network such as the Internet.

  The program executed by the management apparatus M according to the present embodiment has a module configuration including the above-described units (counter unit determination units 102 and 202, service management units 103 and 203). As actual hardware, a CPU ( When the Central Processing Unit) reads out the program from the ROM and executes it, the above-described units are loaded on the main storage device, and the opposing device determination units 102 and 202 and the service management units 103 and 203 are generated on the main storage device. It is like that.

  The program executed by the voice server S according to the present embodiment has a module configuration including the above-described units (the message receiving unit 107, the voice path control unit 108, and the service selection unit 109). When the program is read from the ROM and executed, each unit is loaded onto the main storage device, and the message receiving unit 107, the voice path control unit 108, and the service selection unit 109 are generated on the main storage device. ing.

  The program executed by the network device PS according to the present embodiment has a module configuration including the above-described units (service determination unit 112, message transmission units 113 and 213, and voice path control units 114 and 214). As the hardware, the CPU reads the program from the ROM and executes it, so that the respective units are loaded onto the main storage device, and the service determination unit 112, the message transmission units 113 and 213, and the voice path control units 114 and 214 include It is supposed to be generated above.

  The program executed by the high-performance network device HPS of the present embodiment has a module configuration including the above-described units (message receiving unit 207, voice path control unit 208, service selection unit 209), and as actual hardware When the CPU reads the program from the ROM and executes it, the above units are loaded onto the main storage device, and the message receiving unit 207, the voice path control unit 208, and the service selection unit 209 are generated on the main storage device. It has become.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

1, 2 Communication system 101, 201 System information management unit 102, 202 Opposite device determination unit 103, 203 Service management unit 106, 206 High function DSP unit 107, 207 Message reception unit 108, 208 Voice path control unit 109, 209 Service selection Unit 110 voice server management information storage unit 111 DSP unit 112 service determination unit 113, 213 message transmission unit 114, 214 voice path control unit 210 high-function network device management information storage unit M, M1 management device S voice server PS network device LT local Terminal NW network

Claims (13)

Among the functions executable for sound data, a data format that can transfer the sound data transmitted from the first terminal in the first network to a second terminal in a second network different from the first network A processing unit having a first function of converting the data into the second terminal,
Among the functions of the processing unit, the second information that is received from the first terminal is instructed to execute a second function other than the first function, and the second function that is instructed to be executed by the received first information When the processing unit does not have, the communication unit that transmits the second information that instructs the execution of the second function to the first external device,
When the third information indicating that the second function can be executed is received from the first external device, a path used for transferring the sound data to the second terminal is passed through the first external device. A control unit as a path for transferring sound data to the second terminal;
A communication control device.   2. The communication according to claim 1, wherein, when the processing unit does not have the second function, the communication unit transmits the second information including information that can identify the second function to the first external device. Control device.   When the communication unit receives, from the first external device, fourth information capable of executing the second function and identifying a second external device other than the first external device, the second terminal The communication control apparatus according to claim 1, wherein a path used for transferring the sound data with respect to is a path for transferring the sound data to the second terminal via the second external device.   When the control unit receives the third information, the control unit sets the transfer destination of the sound data to the first external device, and the sound data via the first external device to the second terminal The communication control device according to any one of claims 1 to 3, wherein the fifth information for notifying the path of the first is transmitted.   The communication control device according to claim 4, wherein the control unit sets the transfer destination of the sound data to the first external device after transmitting the fifth information to the second terminal. A processing unit having a function executable for sound data;
A receiving unit that receives, from an external communication control device, first information that instructs execution of a function for the sound data;
When the processing unit has a function instructed to be executed by the received first information, the external communication control device receives second information indicating that the function instructed to be executed by the first information can be executed. A transmitter for transmitting to
A function of controlling the processing unit to receive the sound data transmitted from the first terminal in the first network via the external communication control device, and having the processing unit for the received sound data. A controller that executes and transfers the sound data for which the function has been executed to a second terminal in a second network different from the first network;
A server with   When the processing unit does not have a function instructed to be executed by the received first information, the transmission unit sends second information that enables identification of an external server having the function to the external communication control device. The server according to claim 6 which transmits.   The transmission unit sends the second information that enables the external server having the lowest function among the external servers having a function instructed to be executed by the received first information to the external communication control device. 8. The server according to claim 7, wherein the server is transmitted.   The transmission unit sends the second information that enables the external server having the smallest load to be identified from the external server having the function instructed to be executed by the received first information to the external communication control device. The server according to claim 7 for transmitting.   The transmission unit is configured to identify the second information that enables the external server having the same geographical information as the geographical information of the server to be identified from the external server having a function instructed to be executed by the received first information. The server according to claim 7, which transmits to the external communication control device. A communication system having a communication control device and a server,
The communication control device includes:
Among the functions executable for sound data, a data format that can transfer the sound data transmitted from the first terminal in the first network to a second terminal in a second network different from the first network A first processing unit having a first function of converting to and transferring to the second terminal;
Among the functions of the first processing unit, first information that instructs execution of a second function other than the first function is received from the first terminal, and execution is instructed by the received first information. If the first processing unit does not have two functions, a communication unit that transmits second information that instructs execution of the second function to the server;
When the third information indicating that the second function can be executed is received from the server, a path used for transferring the sound data to the second terminal is transmitted to the second sound data via the server. A control unit as a path to be transferred to the terminal;
With
The server
A second processing unit having a function executable on the sound data;
A receiving unit for receiving the second information from the communication control device;
When the second processing unit has a function instructed to be executed by the received second information, a transmission unit that transmits the third information to the communication control device;
The second processing unit is controlled to receive the sound data transmitted from the first terminal via the communication control device, and the function of the second processing unit is performed on the received sound data A controller that transfers the sound data on which the function has been executed to the second terminal;
A communication system comprising: Among the functions executable for sound data, a data format that can transfer the sound data transmitted from the first terminal in the first network to a second terminal in a second network different from the first network A communication control method executed by a communication control device including a processing unit having a first function of converting to a second terminal,
Receiving first information from the first terminal that instructs execution of a second function other than the first function among the functions of the processing unit;
If the processing unit does not have the second function for which execution is instructed by the received first information, the second information for instructing execution of the second function is transmitted to the first external device,
When the third information indicating that the second function can be executed is received from the first external device, a path used for transferring the sound data to the second terminal is passed through the first external device. A path for transferring sound data to the second terminal;
A communication control method. A communication control method executed by a server including a processing unit having a function executable for sound data,
Receiving, from an external communication control device, first information instructing execution of a function for the sound data;
When the processing unit has a function instructed to be executed by the received first information, the external communication control device receives second information indicating that the function instructed to be executed by the first information can be executed. Send to
A function of controlling the processing unit to receive the sound data transmitted from the first terminal in the first network via the external communication control device, and having the processing unit for the received sound data. Executing and transferring the sound data on which the function has been executed to a second terminal in a second network different from the first network;
A communication control method.

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