JP2013110668A - Method of making information for use in call control redundant and call control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method of making information for use in call control redundant and a call control system that facilitate efficient and quick system switchover in a redundant call control system.SOLUTION: An active call control server 61 transfers, to a standby call control server 62 at a predetermined timing, data about changes of information on ongoing call processing at the active call control server. The standby call control server 62 updates information on ongoing call processing stored in a synchronized area storage 624 in the standby call control server with the data about changes of information on ongoing call processing transferred by the active call control server 61. When a processing data storage 622 of the standby call control server 62 detects that the information stored in the synchronized area storage 624 is updated, the standby call control server retrieves the updated information and loads it into an area in the processing data storage 622 in the standby call control server for use in call processing in the case of activation of the standby call control server.

Description

  The present invention relates to a redundancy method for information used for call control and a call control system.

  Conventionally, SIP (Session Initiation Protocol), which is a communication control protocol, has been developed as a technique for controlling session establishment by call control. This SIP makes it possible to perform media communication such as voice information and video information between user terminals using the IP network while maintaining the high quality, reliability, and stability that the fixed telephone network has. To do.

  Call control by SIP is executed between a subscriber terminal used by an end user and an SIP server that relays communication between the subscriber terminals and between a plurality of SIP servers connected via an IP network.

  In order to establish communication by this call control with high reliability, as shown in Non-Patent Document 1 and Patent Document 1, the ACT (active) call control server and the SBY (standby) call control server are made redundant. There is a technology that uses the call control system.

  In this call control system, information regarding session establishment is synchronized at a predetermined timing between the ACT (active) call control server and the SBY (standby) call control server, and in normal times, the ACT (active) system is synchronized. Call control is executed by the call control server. When a failure occurs in the ACT (active) call control server, the call control server is switched to the SBY (standby) call control server to execute call control.

  By making the servers that perform call control redundant in this way, it is possible to prevent communication from being disconnected due to a failure at a timing not intended by the user.

Yusuke Ogata, Daisuke Hara, Kazumasa Matsuo, Yoshiki Emura: A method for reducing call switching server switching time, Proceedings of the 2010 IEICE General Conference, B-6-15 (Mar.2010).

JP 2011-175382 A

  In the call control systems of Non-Patent Document 1 and Patent Document 1 described above, information regarding session establishment transferred from the ACT (active) call control server during synchronization processing is synchronized with the SBY (standby) call control server. Stored in the area.

  When a failure occurs in the ACT (active) call control server and the server that performs call control is switched, the SBY (standby) call control server expands the information stored in the synchronization area into the heap area. Call processing is resumed.

  However, when the information expansion process from the synchronous area to the heap area is performed in the SBY (standby) system call control server at the time of system switching in this way, it takes time for the expansion process to resume call control. There was a problem that system switching took time.

  Therefore, an object of the present invention is to provide an information redundancy method and a call control system for use in call control for efficiently executing system switching processing in a short time in a redundant call control system.

  In order to solve the above-mentioned problem, the information redundancy method used for call control according to the present invention controls call processing between a plurality of SIP servers that execute call processing, and operates in normal operation. And the standby call control server of the active call control server, which is switched to the active system and operates when a failure occurs in the active call control server. Storing information related to call processing being processed by the server in a synchronization area storage unit within the server; and a change of information regarding call processing being processed by the active call control server in the server A step of transferring to the standby call control server at a transfer timing; and the standby call control server transfers the call being processed transferred from the active call control server by the synchronization processing control unit in the own server. The information stored in the synchronization area storage unit is updated in the step of updating the information stored in the synchronization area storage unit, and the processing data storage unit in the standby call control server A step of acquiring the updated information from the synchronous area storage unit when it is detected, and expanding it into an area in the processing data storage unit for use in call processing when the local server operates. It is characterized by having.

  In the processing data storage unit of the standby call control server, the information stored in the synchronization area storage unit has been updated as a result of confirming whether or not the synchronization area storage unit has been updated at predetermined time intervals. Or when it is detected that the information stored in the synchronization area storage unit has been updated by being notified of the update from the synchronization area storage unit. May be acquired from the synchronous area storage unit and expanded into an area in the processing data storage unit.

  The call control system of the present invention controls call processing between a plurality of SIP servers that execute call processing, and is used when a failure occurs in the active call control server that operates normally and the active call control server. A standby call control server that operates by switching to the active system, wherein the active call control server indicates a change in information related to call processing being processed by the server at a predetermined transfer timing. The standby call control server stores information related to call processing being processed by the active call control server, and stores the stored information. A synchronization region storage unit that updates the information related to the call processing being processed transferred from the active call control server, and detects that the information stored in the synchronization region storage unit has been updated. Occasionally, to obtain the information the update from said synchronization field storage unit, and having a processing data storage unit to expand the area for use by the call processing when the local server is running.

  According to the information redundancy method and call control system used for call control according to the present invention, it is possible to execute the system switching process efficiently and in a short time in the redundant call control system.

1 is an overall view showing a configuration of a SIP communication system using a call control system according to an embodiment of the present invention. It is a block diagram which shows the structure of the call control system by one Embodiment of this invention. It is a block diagram which shows the structure of the call process control part of the call control system by one Embodiment of this invention. It is explanatory drawing which shows an example of the sequence pattern performed with the server in the call control system by one Embodiment of this invention. It is explanatory drawing which shows the structure of the memory | storage part of the ACT (working) type call control server in the call control system by one Embodiment of this invention. It is explanatory drawing which shows the structure of the memory | storage part of the SBY (standby) type | system | group call control server in the call control system by one Embodiment of this invention. It is a flowchart which shows the operation | movement in the server in the call control system by one Embodiment of this invention. It is explanatory drawing which shows the relief data transfer timing on the sequence performed with the server in the call control system by one Embodiment of this invention. It is a flowchart which shows the expansion | deployment operation | movement of the information at the expansion | deployment timing based on polling to the process data storage part of the SBN (standby) type call control server in the call control system by one Embodiment of this invention. It is a flowchart which shows the expansion | deployment operation | movement of the information at the expansion | deployment timing based on an event drive to the process data storage part of the SBN (standby) type call control server in the call control system by one Embodiment of this invention.

  In the call control system according to an embodiment of the present invention, one or more SIP servers are connected before and after, and SIP signals are transmitted / received to / from these SIP servers according to a series of processing sequence (step) information set in advance. Thus, a call is established and a media communication service can be provided.

  This preset processing sequence information is a combination of “sequence pattern”, which is a sequence part of detailed processing units such as call connection, response, and disconnection, which constitute a part of a series of call control sequence processes, in a predetermined execution order. Is configured.

<Configuration of SIP Communication System Using Call Control System According to One Embodiment>
A configuration of a SIP communication system 1 using a call control system according to an embodiment of the present invention will be described with reference to FIG.

  The SIP communication system 1 according to the present embodiment is a proxy server connected to a plurality of subscriber terminals 2A to 2D and the subscriber terminal 2A and the subscriber terminal 2B among these subscriber terminals via the IP network 3. SIP server 4A, SIP server 4B, which is a proxy server connected to subscriber terminal 2C and subscriber terminal 2D via IP network 3, and a plurality of servers on IP network 3 connected to SIP server 4A and SIP server 4B Transfer devices 3A to 3G, relay servers 5A and 5B for relaying between SIP server 4A and SIP server 4B, and call control system 6 connected to SIP server 4A, SIP server 4B, relay server 5B, and the like And media servers 7A and 7B on the IP network 3 connected to the call control system 6The traffic of media information such as audio information and video information is transferred between the subscriber terminals 2A to 2D or between the subscriber terminals 2A to 2D and the media servers 7A and 7B via the transfer devices 3A to 3G on the IP network 3. Transferred between.

  Each of the subscriber terminals 2A to 2D is an IP phone, an HGW (home gateway) or the like used by a subscriber who is a user, and media communication used between subscriber terminals such as voice information and video information using SIP. A function of performing SIP negotiation for performing The subscriber terminals 2A to 2D have a function of performing media communication under signal conditions determined as a result of SIP negotiation.

  The transfer devices 3A to 3G are located in the IP network 3 and transfer media communication traffic between the subscriber terminals 2A to 2D.

  The SIP server 4A is a proxy server that relays the SIP signals of the subscriber terminals 2A and 2B, and the SIP server 4B is a proxy server that relays the SIP signals of the subscriber terminals 2C and 2D. The SIP servers 4A and 4B have a function of relaying SIP negotiations between subscriber terminals and supplementing based on subscriber contract information, and a function of editing a SIP signal according to a rule stored in advance.

  The relay servers 5A and 5B have a function of connecting to the SIP server 4A and the SIP server 4B and relaying SIP signals.

  The call control system 6 includes an ACT (active) call control server 61 and an SBY (standby) call control server 62 constructed as a cluster system as shown in FIG. Based on the subscriber contract information type and the requested service at the server, control of call establishment and disconnection between the SIP servers 4A and 4B is performed, and the media servers 7A and 7B and the subscriber terminals 2A to 2D SIP negotiation is performed so that media communication can be performed. In addition, the SIP signal is edited and the SIP negotiation is relayed to establish a call so that subsequent media communication between the subscriber terminals 2A to 2D can be performed.

  FIG. 1 shows a case where two SIP servers (proxy servers) 4A, 4B, two media servers 7A, 7B, etc. are connected to the call control system 6. It is possible to control the establishment and disconnection of a plurality of calls between these devices.

  At normal times, the ACT (active) call control server 61 operates. When a failure occurs in the ACT (active) call control server 61, the SBY (standby) call control server 62 switches to the active system and operates. To do.

  As shown in FIG. 2, the ACT (active) call control server 61 includes a first call processing control unit 611, a first processing data storage unit 612, a first synchronization processing control unit 613, and a first synchronization area storage unit. 614. As an example of the configuration of the first call processing control unit 611, an example in which a plurality of functional units classified based on processing contents are hierarchically constructed will be described with reference to FIG.

  The first call processing control unit 611 in the present embodiment includes a transport function unit 6111, a received signal buffer 6112, a protocol function unit 6113, a user agent (UA) function unit 6114, a sequence function unit 6115, and a service function. Unit 6116 and a transmission signal buffer 6117. The transport function unit 6111, the protocol function unit 6113, the user agent (UA) function unit 6114, the sequence function unit 6115, and the service function unit 6116 are service functions having higher functions from the transport function unit 6111 having lower functions. The unit 6116 is hierarchically constructed.

  The transport function unit 6111 includes a reception processing unit 6111a that executes a parsing process (preprocessing) for processing the received SIP signal by the own device when the received SIP signal is received, and a transmission signal when the transmission SIP signal is transmitted. A transmission processing unit 6111b that performs a reverse parsing process for generating a SIP signal for transmission based on information in the buffer 6117.

  The reception signal buffer 6112 holds reception signal information parsed by the transport function unit 6111. By holding the information after the parsing process in the reception signal buffer 6112, it becomes possible to refer to the reception signal after the parsing process in the protocol function unit 6113 and the UA function unit 6114, which will be described later. Can be executed.

  The protocol function unit 6113 refers to the received signal buffer, analyzes the received signal information that has been parsed according to the protocol, and generates dialog information or signals as an interface used for communication by call processing with the calling / receiving subscriber terminal 2. Receiving processing unit 6113a that acquires and holds transaction information to be updated, timer information for maintaining a dialog, and the like, dialog information and transaction information for transmission SIP generation, and timer information for maintaining a dialog And the like, and a transmission processing unit 6113b that transmits the information to the transmission signal buffer 6117 as information used for generating the transmission SIP signal.

  Since the transmission / reception of the SIP signal is always performed in a server-client relationship, when the calling side is a UAC (User Agent Client), the UA function unit 6114 includes a UAS (User Agent Server) 6114a corresponding to the calling side, When the called side is a UAS (User Agent Server), it has a UAC (User Agent Client) 6114b corresponding to this called side, and these cooperate to perform processing related to communication with the SIP server on the called side.

  As described above, the UAS 6114a and the UAC 6114b are provided in the UA function unit 6114, and the UAS 6114a and the UAC 6114b cooperate to communicate with the server / terminal on the outgoing / incoming side. Can function as both UAS and UAC, and has a mechanism to execute services by linking UAS 6114a and UAC 6114b, so that it is possible to provide advanced services that are difficult to realize with a conventional simple proxy server. It is also possible to provide it to the outgoing / incoming side. Further, since communication is possible while maintaining the relationship between the UAS 6114a and UAC 6114b on the outgoing / incoming side, there is an advantage that it is easy to maintain the network policy.

  The UAS 6114a refers to the received signal buffer 6112, determines the type of the received SIP signal from the parsed received signal information, and from this determined type, the SIP signal to respond to the return transmission source regardless of the stage in the processing sequence When the type (status code) is uniquely specified according to the protocol, the SIP signal of the specified type is processed through processing by the reception processing unit 6113a of the protocol function unit 6113 and the reception processing unit 6111a of the transport function unit 6111. If the SIP signal type to be responded is not uniquely specified by the determined type, the host sequence function unit 6115 is notified.

  For example, the UAS 6114a refers to the received signal buffer 6112 to acquire the Call-ID, remote tag, local tag, etc. of the received SIP signal, and confirms whether this is stored as call control information in the local server 61, When it is not held in the local server 61 as call control information, it is determined that the re-INVITE signal is one of the refresh signals for maintaining the already established call.

  For the re-INVITE signal, the status code of the signal to be returned can be specified as “200 (response)” regardless of the call control sequence information. The information of the status code “200 (response)” can be specified. Is sent to the reception signal buffer 6112.

  Further, when the Call-ID of the received SIP signal acquired by the UAS 6114a is held as call control information in the local server 61, for example, it is determined that the received SIP signal is a PRACK signal as a provisional response during call control. Sometimes, the sequence function unit 6115 is notified of the information that the received SIP signal is the “PRACK signal”.

  The UAC 6114b sends to the transmission signal buffer 6117 the status code of the signal to be transmitted specified by the sequence function unit 6115, which will be described later, and the information of the destination SIP server specified based on the status code. The held destination information is deleted (invalidated) by releasing the corresponding part of the memory when the call is disconnected. Alternatively, a release status may be set when the call is disconnected, and a timer may be set and deleted upon timeout.

  The sequence function unit 6115 selects a processing sequence (process) pattern related to the processing of the service being executed, holds it in a memory (not shown) in the own apparatus, and based on the signal type of the received SIP signal from the UA function unit 6114. When it is notified that the status code of the signal to be responded cannot be uniquely specified, the current stage in the held processing sequence pattern is specified. Based on this stage, a signal to be transmitted next (for example, “Init-INVITE”, “180 (ringing)”, “PRACK”, “200 (response)”, etc.) is generated to generate a transmission SIP signal. To be specific.

  An example of the processing sequence pattern is shown in FIG. 4A is a sequence pattern a of the call connection portion, FIG. 4B is a sequence pattern b of the response portion after the call is established, and FIG. 4C is a sequence pattern c of the call disconnection portion. . The sequence pattern includes transmission / reception with a server connected to the signal transmission side (transmission side in the call control system 6) and transmission / reception with the server connected to the transmission side (reception side in the call control system 6). And a called-side sequence pattern. The originating side sequence pattern and the terminating side sequence pattern are linked. For example, based on the type of signal received according to the originating side sequence pattern, the type of signal to be transmitted next and the UA function unit 6114 correspond to the type of signal to be transmitted. UAS 6114a and UAC 6114b are specified according to the destination sequence pattern.

  For example, when the received SIP signal is a PRACK signal, the sequence function unit 6115 specifies the signal to be transmitted as “PRACK” for generation of the transmitted SIP signal.

  Here, when the sequence function unit 6115 determines that the sequence pattern being processed has been completed to the end, the sequence function unit 6116 deletes (invalidates) the stored sequence pattern information by releasing the corresponding part of the memory, and also the service function unit 6116. To notify. The deletion of the sequence pattern may be executed after a new sequence pattern is instructed and held by notifying the service function unit 6116 as described later, or the timer is set to a release status when the sequence pattern is completed. It may be set and deleted upon timeout.

  The service function unit 6116 manages a scenario, which is the execution sequence of the sequence pattern used in the sequence function unit 6115, based on the service content subscribed at the calling / receiving subscriber terminal 2, and the sequence being processed by the sequence function unit 6115 When it is notified that the pattern processing is completed, the sequence function unit 6115 is instructed on the sequence function to be executed next based on this scenario.

  For example, a processing sequence in which each sequence pattern in FIG. 4 is executed in the order of sequence pattern a → sequence pattern b → sequence pattern c is stored in advance as a service content of a series of call connection processing. The sequence function unit 6115 is instructed for the next sequence pattern to be processed.

  Among the above function units, the transport function unit 6111, the protocol function unit 6113, and the UA function unit 6114 execute SIP signal processing according to the protocol in units of signals, and the sequence function unit 6115 and the service function unit 6116 execute services. And processes related to control.

  The transmission signal buffer 6117 transmits the status code of the signal to be transmitted sent from the UAC 6114b of the UA function unit 6114, the destination information, the dialog information sent from the transmission processing unit 6113b of the protocol function unit 6113, and the transaction information. This information is stored as information for generating a SIP signal.

  The first processing data storage unit 612 is a heap area of the memory, and information regarding processing executed by each function unit of the first call processing control unit 611 is temporarily expanded and stored for each call and each function unit. And used for continuation of call processing. The configuration of the first processing data storage unit 612 will be described with reference to FIG.

  The first processing data storage unit 612 has an area for storing information for each session, and stores a first session information area 612A for storing information used for processing of the first session and information used for processing of the second session. A second session information area 612B, and a third session information area 612C that stores information used for processing the third session.

  The first session information area 612A, the second session information area 612B, and the third session information area 612C are areas that hold data related to different calls (sessions), and are necessary for processing one call in each section. It is possible to hold various data. Each of these session information areas 612A to 612C includes transport function part information areas 6121A to 6121C for storing information related to processing of the transport function part 6111 of the first call processing control part 611, and information related to processing of the protocol function part 6113. Protocol function part information areas 6122A to 6122C for storing information, UA function part information areas 6123A to 6123C for storing information related to processing of the UA function part 6114, and sequence function part information area for storing information related to processing of the sequence function part 6115 6124A to 6124C and service function part information areas 6125A to 6125C for storing information related to processing of the service function part 6116. In the transport function part information areas 6121A to 6121C, reception processing part information areas 6121A (a) to 6121C (a) for storing information related to processing of the reception processing part 6111a and information related to processing of the transmission processing part 6111b are stored, respectively. The transmission processing unit information areas 6121A (b) to 6121C (b), and the protocol function unit information areas 6122A to 6122C each store information related to the processing of the reception processing unit 6113a. To 6122C (a) and transmission processing unit information areas 6122A (b) to 6122C (b) for storing information related to the transmission processing unit 6113b. The UA function unit information areas 6123A to 6123C each have information on processing of the UAS 6114a. UAS information area 6123 for storing Having (a) ～6123C UAC information area 6123A for storing information relating to (a) and UAC6114b (b) ~6123C (b).

  The first synchronization processing control unit 613 transmits and receives a transfer control signal to and from the second synchronization processing control unit 623 of the SBY (standby) system call control server 62, thereby ACT (working) system call control server 61. To the SBY (standby) call control server 62 from the ACT (standby) call control server 61 for synchronizing the information stored in the SBY (standby) call control server 62 with the information stored in the SBY (standby) call control server 62. Controls the information transfer process.

  The first synchronization area storage unit 614 has a fixed area corresponding to each function unit of the first call processing control unit 611. The configuration of the first synchronization area storage unit 614 will be described in detail with reference to FIG.

  The first synchronization area storage unit 614 has an area for storing information for each session, and stores a first session information area 614A for storing information used for the processing of the first session and information used for the processing of the second session. A second session information area 614B for storing information and a third session information area 614C for storing information used for processing the third session.

  The first session information area 614A, the second session information area 614B, and the third session information area 614C are areas that hold data relating to different calls (sessions), and are necessary for processing one call in each section. It is possible to hold various data. Each of these session information areas 614A to 614C includes transport function part information areas 6141A to 6141C for storing information related to processing of the transport function part 6111 of the first call processing control part 611, and information related to processing of the protocol function part 6113. Protocol function part information areas 6142A to 6142C for storing information, UA function part information areas 6143A to 6143C for storing information related to processing of the UA function part 6114, and sequence function part information area for storing information related to processing of the sequence function part 6115 6144A to 6144C, service function part information areas 6145A to 6145C for storing information related to processing of the service function part 6116, data management information areas 6146A to 6146C for comprehensively managing these information, and a spare area 6 And a 47A~6147C.

  The processing of the transport function unit 6111 includes parsing processing and signal generation processing, and information related to these includes reception SIP signal information and transmission SIP signal information.

  Further, the transaction processing of the protocol function unit 6113 includes transaction identification, retransmission signal processing, and monitoring processing of a timer for maintaining a dialog. Information on these includes time information when the timers of various timers expire, SIP There is a branch parameter information of a Via header, which is a route bus of a request or response by a signal, a Cseq header information related to a transaction, an Rseq header information and the like.

  The processing of the UA function unit 6114 includes dialog management processing, transaction management processing, SIP signal control processing, and the like. Information relating to these includes TO header information indicating the request sender, message sender, and the like. From header information indicating the proxy, Route header information indicating the routing of the proxy, Record-Route header information indicating the route record of the request inserted by the proxy, Contact header information indicating the contact address of the message sender, tag parameter information of the To header And tag parameter information of From header.

  Further, the sequence function unit 6115 includes a sequence execution process, and information related thereto includes management information of UA used in the service.

  The processing of the service function unit 6116 includes service determination processing, scenario execution processing, media replacement processing, media change processing, and the like. Information regarding these includes SDP information (media information), contractor data ( Conversion-source and conversion-destination telephone number data, etc.) and system-dependent data.

  The SBY (standby) system call control server 62 includes a second call processing control unit 621, a second second processing data storage unit 622, a second synchronization processing control unit 623, and a second synchronization area storage unit 624. Have.

  The second call processing control unit 621 includes a transport function unit 6211, a received signal buffer 6212, a protocol function unit 6213, a user agent (UA) function unit 6214, a sequence function unit 6215, a service function unit 6216, A transmission signal buffer 6217, which operates when the SBY (standby) call control server 62 operates. Since the functions of these functional units are the same as the functions of the corresponding functional units of the first call processing control unit 611 of the ACT (active) call control server 61, detailed description thereof will be omitted.

  The second process data storage unit 622 acquires data necessary for the process being executed from the second synchronization area storage unit 624 at a predetermined timing even when the ACT (active) call control server 61 is operating. When the SBY (standby) system call control server 62 is in operation, information relating to processing executed by each function unit of the second call processing control unit 621 is temporarily stored, and the ACT (current) system is stored. This is used for continuation of call processing when a failure occurs in the call control server 61 and the own server switches to the active system and operates. The configuration of the second processing data storage unit 622 will be described with reference to FIG.

  The second processing data storage unit 622 has an area for storing information for each session, and stores a first session information area 622A for storing information used for processing of the first session and information used for processing of the second session. A second session information area 622B, and a third session information area 622C that stores information used for processing the third session.

  The first session information area 622A, the second session information area 622B, and the third session information area 622C are areas that hold data relating to different calls (sessions), and are necessary for processing one call in each section. It is possible to hold various data. Each of these session information areas 622A to 622C includes transport function part information areas 6221A to 6221C for storing information related to processing of the transport function part 6211 of the second call processing control part 621, and information related to processing of the protocol function part 6113. Protocol function part information areas 6222A to 6222C for storing information, UA function part information areas 6223A to 6223C for storing information about processing of the UA function part 6214, and sequence function part information area for storing information about processing of the sequence function part 6215 6224A to 6224C, and service function part information areas 6225A to 6225C for storing information related to processing of the service function part 6216. The transport function unit information areas 6221A to 6221C store reception processing unit information areas 6221A (a) to 6221C (a) that store information related to the processing of the reception processing unit 6211a and information related to processing of the transmission processing unit 6211b, respectively. It has transmission processing section areas 6221A (b) to 6221C (b), and each of the protocol function section information areas 6222A to 6222C stores information related to processing of the reception processing section 6213a. 6222C (a) and transmission processing unit area 6222A (b) to 6222C (b) for storing information related to transmission processing unit 6213b. Each of UA function unit information areas 6223A to 6223C stores information related to processing of UAS 6214a. UAS information area 6223A (a) Having a 6223C (a) and stores information on UAC6214b UAC information area 6223A (b) ~6223C (b).

  The second synchronization processing control unit 623 is stored in the ACT (active) call control server 61 by transmitting and receiving signals related to transfer control with the first synchronization processing control unit 613 of the ACT (active) call control server 61. The information from the ACT (active) call control server 61 to the SBY (standby) call control server 62 to synchronize the stored information with the information stored in the SBY (standby) call control server 62. Control processing.

  The second synchronization area storage unit 624 has a fixed area corresponding to each function unit of the second call processing control unit 621. The configuration of the second synchronization area storage unit 624 will be described in detail with reference to FIG.

  The second synchronization area storage unit 624 has an area for storing information for each session, and stores a first session information area 624A for storing information used for the processing of the first session and information used for the processing of the second session. A second session information area 624B, and a third session information area 624C for storing information used for processing the third session.

  The first session information area 624A, the second session information area 624B, and the third session information area 624C are different sections, and can be written in parallel in the memory, and each section is exclusive from the other sections. Can be locked. That is, while the lock is applied, the section can be in a state where information relating to other than the processing cannot be written.

  The first session information area 624A, the second session information area 624B, and the third session information area 624C are transports corresponding to the transport function part information areas 6141A to 6141C of the ACT (active) call control server 61, respectively. Functional part information areas 6241A to 6241C, protocol functional part information areas 6242A to 6242C corresponding to protocol functional part information areas 6142A to 6142C, UA functional part information areas 6243A to 6243C corresponding to UA functional part information areas 6143A to 6143C, and , Sequence function part information areas 6244A to 6244C corresponding to sequence function part information areas 6144A to 6144C, and service function part information areas 6245A to 6245 corresponding to service function part information areas 6145A to 6145C. It has a 5C, the data management information area 6246A~6246C corresponding to the data management information area 6146A～6146C, a spare area 6247A～6247C.

  The number of sections respectively provided in the first synchronization area storage unit 614 of the ACT (active) system call control server 61 and the second synchronization area storage unit 624 of the SBY (standby) system call control server 62 is the number of calls (sessions). In this embodiment, a case has been shown in which both synchronization area storage units have three sections so as to correspond to three calls (sessions). A section may be provided. A plurality of sessions may be assigned to one call (session).

<Operation of SIP Communication System Using Call Control System According to One Embodiment>
In the SIP communication system 1 according to an embodiment of the present invention, call control from a subscriber terminal 2A or 2B, which is a calling terminal, to a subscriber terminal 2C or 2D via a SIP server 4A, a call control system 6, or a SIP server 4B. The operation of the ACT (active) call control server 61 of the call control system 6 when the SIP signal is transmitted will be described with reference to the flowchart of FIG.

  In the present embodiment, the first synchronization processing control unit 613 maintains the call connection when the ACT (active) call control server 61 is switched to the SBY (standby) call control server 62 in the event of a failure. Of the relief data that is necessary information, information relating to the relief data transfer timing that is the timing to transfer from the ACT (active) call control server 61 to the SBY (standby) call control server 62 is held in advance. And Details of the relief data transfer timing will be described later.

  First, when an Init-INVITE signal for establishing a new call is transmitted from the SIP server 4A, the first call processing control unit 611 determines whether the call is a call signal or a session refresh signal for the INVITE signal. Determined.

  Here, it is determined that the data stored in the reception signal buffer 6112, the transmission signal buffer 6117, and the respective function units is no new call control in the first processing data storage unit 612, and the service function unit 6116 makes an incoming / outgoing call. A sequence function to be executed is instructed to the sequence function unit 6115 based on the scenario of the service content subscribed at the subscriber terminal 2. It is also possible to instruct to select a plurality of sequence patterns at the same time according to the service.

  In the sequence function unit 6115, the sequence pattern (for example, sequence pattern a) instructed from the service function unit 6116 is selected and held as a sequence pattern to be executed.

  After the sequence pattern to be executed is held, the Init-INVITE signal received from the SIP server 4A (S1) is a parse for processing the received SIP signal by the reception device 6111a of the transport function unit 6111 in its own device. Processing (pre-processing) is executed (S2). Specifically, processing such as adding identification information “1” to the first byte to make it easy to identify in the apparatus that the received SIP signal is an Init-INVITE signal is performed. The received signal information subjected to the parsing process is held in the received signal buffer 6112.

  Information acquired by the parsing process is stored in the first process data storage unit 612 of the ACT (active) call control server 61. The information held in the received signal buffer 6112 is stored in a corresponding area of the first processing data storage unit 612 of the ACT (working) call control server 61.

  Next, the reception signal buffer 6112 is referred to in the reception processing unit 6113a of the protocol function unit 6113, the received signal subjected to the parsing process is analyzed according to the protocol, and the dialog information, transaction information, and dialog of the calling / receiving subscriber terminal 2 are maintained. Timer information and the like are acquired (S3). The acquired dialog information, transaction information, timer information for maintaining the dialog, and the like are stored in a corresponding area of the first processing data storage unit 612 of the ACT (active) call control server 61. The reception process is completed by the process so far (S4).

  When the reception process is completed, the transport function unit 6111 of the first call processing control unit 611 determines whether or not this point is the repair data transfer timing based on the identification information of the received SIP signal acquired by the parsing process. It is determined (S5).

  The relief data transfer timing in the present embodiment will be described with reference to FIGS.

  FIG. 8A shows, in sequence, the order of transmission / reception of each SIP signal for each call between SIP servers when the call control process is executed.

  As shown in FIG. 8A, in the ACT (active) system call control server 61, an Init-INVITE signal indicating a call start request is transmitted from the originating SIP server 4A (S21), and is being tried. A Trying (100) signal indicating this is returned to the SIP server 4A (S22), and an Init-INVITE signal is transferred to the SIP server 4B on the receiving side (S23). Then, a Trying (100) signal as a reply to the Init-INVITE signal transferred to the SIP server 4B is received (S24).

  Thereafter, when receiving the Ringing (180) signal indicating that the call is being made at the subscriber terminal on the called side from the SIP server 4B (S25), the signal is transferred to the SIP server 4A on the calling side (S26). A PRACK signal is received as a provisional response (S27).

  Next, the received PRACK signal is further transmitted to the SIP server 4B on the receiving side (S28), and a 200 (PRACK) signal is received as a provisional response thereto (S29), which is further transferred to the SIP server 4A on the calling side. (S30).

  Thereafter, when 200 (Init-INVITE) indicating that a response has been made at the subscriber terminal on the called side is received from the SIP server 4B (S31), this is transferred to the SIP server 4A on the calling side (S32). That the user terminal has responded.

  Correspondingly, when an ACK signal indicating call establishment approval is transmitted from the SIP server 4A on the transmission side (S33), it is transferred to the SIP server 4B on the reception side (S34), and communication is started.

  FIG. 8B is a sequence in the case where session refresh is executed by a re-INVITE signal during a call. When a re-INVITE signal from a calling / receiving subscriber terminal is transmitted from the SIP server 4A ( In S41, the call control system 6 responds and returns a 200 signal (S42), whereby an ACK signal is transmitted (S43), the session timer is updated, and the call establishment is maintained.

  Alternatively, when a re-INVITE signal is transmitted from the call control system 6 (S44), the call control system 6 sends back an ACK signal by returning a 200 signal indicating that the subscriber terminal on the outgoing / incoming side has responded (S45). (S46), the session timer is updated, and the call establishment is maintained.

  FIG. 8C shows a sequence in the case where session refresh is executed by the UPDATE signal. When the UPDATE signal is transmitted from the calling / receiving subscriber terminal (S51), the call control system 6 responds. By returning the 200 signal (S52), the session timer is updated and the call establishment is maintained.

  Alternatively, when an UPDATE signal is transmitted from the call control system 6 (S53), the calling / receiving subscriber terminal responds and returns a 200 signal (S54), whereby the session timer is updated and the establishment of the call is maintained. Is done.

  Returning to FIG. 8A, when a BYE signal indicating a call disconnection request is transmitted from the SIP server 4A on the calling side (S35), the call control system 6 returns 200 (BYE) as a response to this (S36). And a BYE signal is transferred to the SIP server 4B on the receiving side (S37). Then, by receiving a 200 (BYE) signal as a reply to the BYE signal transferred to the SIP server 4B (S38), the call is disconnected.

  In the call control process executed in this way, the relief data transfer timing from the ACT (active) call control server 61 to the SBY (standby) call control server 62 is the previous ACT (active) call control server 61. And the SBY (preliminary) system call control server 62 are set at a timing at which the call control process can be recovered according to the protocol even if the information of the changed point after the synchronization process (relief data transfer process) is lost.

  Specifically, (i) resending to the call control server 61 can be expected. If the transmission / reception of the signal is not stored, resending from the call control server 61 is impossible, and the sequence can be restored and continued. When an impossible signal is transmitted / received (for example, when the Init-INVITE signal is transmitted in step S23), and (ii) the fact that the signal has been transmitted / received is not stored, a failure occurs and the sequence rewinds. At the time of transmission / reception of a signal that can be appropriately processed by the call control server 61 (for example, when receiving the Ringing (180) signal in step S25), a transaction of the signal transmitted / received end-to-end is started. Timing to transmit / receive a signal to be transmitted (such as a PRACK or UPDATE signal) or a signal to be terminated (such as a 200 OK signal).

  In the present embodiment, the times indicated by timings t1 to t17 in FIGS. 8A to 8C are set as the relief data transfer timing corresponding to the above (i) or (ii). . When the call control server 61 receives a signal and the signal corresponds to (i) and (ii), the data transfer to the other system (SBY system) is completed in the process of the received signal. On the other hand, when the call control server 61 transmits a signal and the signal corresponds to (i) and (ii), the data transfer to the other system (SBY system) is completed in the process of generating the transmission signal.

  By setting the relief data transfer timing in this way, for example, a failure occurs before the storage of the Ringing (180) signal received in step S25 in the reception signal buffer 6112 is completed, and the server in operation becomes ACT (current ) When moving from the system call control server 61 to the SBY (standby) system call control server 62, the SBY (preliminary) system call control server 62 does not record the reception of the Trying (100) signal in step S24. Although only the recording related to the transfer of the Init-INVITE signal in S23 remains, even if the process is resumed from the transfer of the Init-INVITE signal in Step S23 again, the process is appropriately continued according to the protocol.

  The information regarding the setting of the repair data transfer timing is designated from the service function unit 6116 as a list of signals that need to be transferred at the stage when the service is determined by receiving the Init-INVITE and determining the service. 6111, the transport function unit 6111 inquires of the sequence function unit 6115 every time a signal is transmitted and received, and whether the sequence function unit 6115 is at the repair data transfer timing from the sequence pattern or not. It may be determined and notified to the transport function unit 6111.

  Returning to FIG. 7, when the Init-INVITE signal is received, it is determined that it is not the relief data transfer timing (“NO” in S5).

  Next, the reception signal buffer 6112 is referred to in the UAS 6114a of the UA function unit 6114, and the address of the SIP server that is the transmission source of the reception SIP signal and the address of the SIP server that is the transmission destination are acquired, and the first processing data storage unit 612 The type of the received SIP signal is determined based on the identification information added by the parsing process, and the status code of the signal to be returned is uniquely identified from the determined type. It is determined whether or not (S6).

  Here, in the UAS 6114a, it is determined that the status code “100 (trying)” signal is returned to the return transmission source according to the protocol for the new “Init-INVITE signal” regardless of the processing sequence, and the first processing data Based on the information held in the storage unit 612, dialog processing and transaction processing are performed by the protocol function unit 6113, and the transport function unit 6111 generates a transmission SIP signal of the status code “100 (trial)” It is transmitted to the SIP server 4A (“YES” in S6, S9 to S11, S22).

  When the transmission SIP signal with the status code “100 (trial)” is transmitted, the UAS 6114a further notifies the sequence function unit 6115 that the new “Init-INVITE signal” has been received (“NO” in S6). ", S7).

  When the sequence function unit 6115 is notified that the “Init-INVITE signal” has been received from the UA function unit 6114, the held processing sequence pattern is selected and the current stage in this sequence is specified ( S8). Here, the current stage in the sequence pattern a of the call connection portion in FIG. 4A is specified, and further, based on this stage, the signal “Init-INVITE” to be transmitted next is held in the UA function unit 6114. UAS 6114a and UAC 6114b are identified. At the current stage in the sequence, the UAC 6114b is instructed to transmit Init-INVITE. In response to the instruction, the UAC 6114b sends information on the Init-INVITE signal to the transmission signal buffer 6117 together with information on the transmission destination held in the first process data storage unit 612 corresponding to the UAC 6114b (S9). The destination information is included in the received Init-INVITE signal, and is stored in the corresponding area of the first processing data storage unit 612 by the UAS 6114a at the time of reception, and the destination information and the like are stored in the UAC 6114b at the above timing. Take over the data. Further, the transmission processing unit 6113 b of the protocol function unit 6113 sends transmission information such as dialog information and transaction information for transmission SIP generation held in the first processing data storage unit 612 to the transmission signal buffer 6117.

  Next, in the transmission processing unit 6111b of the transport function unit 6111, the information in the transmission signal buffer 6117 is used to perform reverse parsing processing to generate a transmission SIP signal (S10). Then, the generated transmission SIP signal is transmitted to the SIP server 4B (S11, S23). Information held in the transmission signal buffer 6117 is stored in a corresponding area of the first processing data storage unit 612 of the ACT (active) call control server 61.

  Here, when the transmission processing of the transmission SIP signal is completed, the transport function unit 6111 of the first call processing control unit 611 determines whether or not this point is the repair data transfer timing based on the identification information of the transmission SIP signal. Is determined (S12).

  Here, a Trying (100) signal is returned to the SIP server 4A in response to the received Init-INVITE signal, and the Init-INVITE signal is transferred to the SIP server 4B. It is determined that t2) is the relief data transfer timing (“YES” in S12).

  If it is determined that it is the relief data transfer timing, the first synchronization processing control unit 613 of the ACT (active) system call control server 61 changes from the first synchronization processing control unit 623 of the SBY (standby) system call control server 62 to First, the section of the call corresponding to the change target in the second synchronization area storage unit 624 of the SBY (standby) call control server 62, for example, the first session information area 624A is not written by a process other than the transfer process. An instruction to enter a locked state is transmitted. Based on this instruction, the second synchronization processing control unit 623 of the SBY (standby) system call control server 62 locks the first session information area 624A of the corresponding call in the second synchronization area storage unit 624. .

  Next, an instruction to write data is sent from the first synchronous processing control unit 613 of the ACT (active) system call control server 61, and this function relates to processing of each functional unit stored in the first processing data storage unit 612. The data includes the corresponding transport function part information area 6141A, protocol function part information area 6142A, UA function part information area 6143A, sequence function part information area 6144A, service function part in the first synchronization area storage unit 614 of the own server 61. Information is written in the information area 6145A and the data management information area 6146A.

  Further, an instruction to transfer data at the rescue point is sent from the first synchronization processing control unit 613 of the ACT (active) call control server 61, and the processing of each functional unit stored in the first processing data storage unit 612 according to this instruction. Is transferred as relief data to the SBY (standby) system call control server 62 (S13). In the SBY (preliminary) system call control server 62, the received relief data is the corresponding functional unit area of the corresponding call information section of the second synchronization area storage unit 624, for example, the corresponding functional unit of the first session information area 624A. Stored in the area.

  As described above, when the write processing of the data in the first processing data storage unit 612 to the own server 61 and the transfer processing of the corresponding relief data to the SBY (standby) call control server 62 are completed, the ACT (active) call An instruction to unlock the corresponding section of the second synchronization area storage unit 624 is transmitted from the first synchronization processing control unit 613 of the control server 61 to the second synchronization processing control unit 623 of the SBY (standby) system call control server 62. Is done. Then, the second synchronization processing control unit 623 of the SBY (preliminary) call control server 62 unlocks the corresponding section of the second synchronization area storage unit 624 based on this instruction.

  When the lock is released, the completion of the instructed writing process and transfer process is notified from the first synchronization processing control unit 613 to the first call processing control unit 611, and the first call processing control unit 611 continues to receive it. SIP signal processing is performed.

  As described above, when the transfer process is executed with the corresponding section of the second synchronization area storage unit 624 in the locked state, it is stored in the corresponding sections of the first synchronization area storage unit 614 and the second synchronization area storage unit 624. It is possible to prevent a difference from being generated in the data.

  Next, the operation of the call control system 6 when a re-INVITE signal, which is one of refresh signals for maintaining an established call, is transmitted from the SIP server 4A.

  When the ACT (active) call control server 61 receives a re-INVITE signal from the SIP server 4A (S1), it is determined whether the call is a call signal or a session refresh signal with respect to the INVITE signal.

  Here, it is determined that the re-INVITE signal is a session refresh signal.

  Next, the reception processing unit 6111a of the transport function unit 6111 executes a parsing process (pre-processing) for processing the received SIP signal by the own apparatus (S2).

  The information acquired by the parsing process is stored in the corresponding area of the first processing data storage unit 612 of the ACT (active) call control server 61 in the change from the previous signal processing.

  Next, the reception signal buffer 6112 is referred to in the reception processing unit 6113a of the protocol function unit 6113, the received signal subjected to the parsing process is analyzed according to the protocol, and the dialog information, transaction information, and dialog of the calling / receiving subscriber terminal 2 are maintained. Timer information and the like are acquired (S3). Changes in the previous signal processing, such as the acquired dialog information, transaction information, and timer information for maintaining the dialog, correspond to the first processing data storage unit 612 of the ACT (active) call control server 61. Stored in the area. The reception process is completed by the process so far (S4).

  When reception processing is completed, based on the identification information of the received SIP signal acquired by the parsing processing in the transport function unit 6111 of the first call processing control unit 611, whether or not this time is the repair data transfer timing It is determined (S5).

  Here, when the re-INVITE signal is received, it is determined that it is not the repair data transfer timing based on the information of FIG. 8B (“NO” in S5).

  Next, the received signal buffer 6112 is referred to in the UAS 6114a of the UA function unit 6114, the address of the SIP server that is the transmission source of the received SIP signal and the address of the SIP server that is the transmission destination are acquired, and the type of the received SIP signal is parsed. A determination is made based on the identification information added in the process, and it is determined from this determined type whether or not the status code of the signal to be returned is uniquely identified (S6). Here, since there is no change in the address of the SIP server that is the transmission source of the received SIP signal and the address of the SIP server that is the transmission destination in the previous signal processing, the change is written to the first processing data storage unit 612. Not done.

  Here, in the UAS 6114a, it is determined that the status code “200 (response)” signal is returned to the return transmission source according to the protocol regardless of the processing sequence for the “re-INVITE signal” (“YES” in S6). ).

  When the status code of the signal to be responded is specified in the UAS 6114a, the status code “200 (response)” is received by the reception processing unit 6111a of the transport function unit 6111 based on the information held in the first processing data storage unit 612. A transmission SIP signal is generated and sent to the SIP server 4A to respond (S9 to S11).

  Here, when the transmission processing of the transmission SIP signal is completed, the transport function unit 6111 of the first call processing control unit 611 determines whether or not this point is the repair data transfer timing based on the identification information of the transmission SIP signal. Is determined (S12).

  Here, a response (200) signal is returned to the SIP server 4A in response to the received re-INVITE signal, and it is determined that this transmission time (timing t11 in FIG. 8) is the relief data transfer timing (“YES” in S12). ").

  If it is determined that it is the relief data transfer timing, the change related to the processing of each functional unit stored in the first processing data storage unit 612 of the ACT (active) call control server 61 by the transfer processing described above, The area of the call information section in the first synchronization area storage unit 614 of the ACT (active) system call control server 61, for example, the transport function part information area 6141A, the protocol function part information area 6142A of the first session information area 614A, and the UA function The section information area 6143A, the sequence function section information area 6144A, the service function section information area 6145A, and the data management information area 6146A are updated and transferred to the SBY (standby) system call control server 62 in a locked state as relief data. Each functional area of the corresponding call information section, eg first session The transport function section information area 6241A, protocol function section information area 6242A, UA function section information area 6243A, sequence function section information area 6244A, service function section information area 6245A, and data management information area 6246A in the information area 624A are updated ( S13).

  As described above, the processing data storage unit 622 of the SBY (standby) call control server 62 stores the second synchronization area in the state where the call control is performed while the transfer of the repair data is executed at the repair data transfer timing. Information of each functional unit stored in the unit 624 is expanded in a corresponding area of the second processing data storage unit 622 to be used when the local server is switched to the active system and operates.

  There are two deployment timings at which the information stored in the second synchronization area storage unit 624 is deployed: (i) the deployment timing based on polling, and (ii) the deployment timing based on event-driven. Each development timing will be described.

(i) Deployment timing based on polling The deployment processing based on the deployment timing based on polling is performed in a state where transfer processing of relief data and notification of completion of this transfer processing are performed as necessary as shown in the flowchart of FIG. These processes are executed separately at a predetermined timing. The operation of the second processing data storage unit 622 of the SBY (preliminary) system call control server 62 relating to this expansion processing will be described with reference to the flowchart of FIG.

  First, the second processing data storage unit 622 monitors whether or not a predetermined time has elapsed from the previous development timing (S61), and when it is determined that this predetermined time has elapsed (" YES ”), it is confirmed whether or not there is an update from the previous deployment timing in the information stored in the second synchronization area storage unit 624 (S62).

  As a result of this confirmation, when it is detected that the information stored in the second synchronization area storage unit 624 has been updated from the previous development timing (“YES” in S62), the second processing data has already been obtained. If there is no actual information developed in each functional unit area of the storage unit 622 (“NO” in S63), the information stored in the second synchronization area storage unit 624 corresponds to the second processing data storage unit 622. It is expanded in the corresponding functional part of the session information area (S64).

  Next, the information updated in the second synchronization area storage unit 624 is acquired in the second processing data storage unit 622 (S65). This process is repeated until all updated information is obtained.

  Then, the information developed in the second process data storage unit 622 in step S64 or the information already developed as determined in “YES” in step S63 is updated and developed with the update information acquired in step S65. (S66).

  In this way, (i) the information stored in the second synchronization area storage unit 624 at the predetermined expansion timing based on polling is expanded in the second processing data storage unit 622 and updated to the latest information, so that the ACT (active ) The first process of the ACT (active) system call control server 61 is stored in the second processing data storage unit 622 of the SBY (standby) system call control server 62 without reducing the efficiency of the call processing in the system call control server 61. Information similar to the information developed in the data storage unit 612 can be developed.

(ii) Deployment timing based on event driven In the deployment processing based on the deployment timing based on event driven, the repair data is transferred from the ACT (active) system call control server 61 to the SBY (standby) system in step S13 or S14 in the flowchart of FIG. It is executed when it is transferred to the call control server 62. The operation of the second processing data storage unit 622 of the SBY (preliminary) call control server 62 relating to the expansion processing will be described with reference to the flowchart of FIG.

  In this expansion process, when the relief data is transferred in step S13 or S14 in the flowchart of FIG. 7 and the information stored in the second synchronization area storage unit 624 is updated, the second synchronization area storage unit 624 updates the information. An update notification is sent to the 2-process data storage unit 622.

  The second processing data storage unit 622 monitors whether or not an update notification has been acquired from the second synchronization area storage unit 624 (S71), and when it is detected that the update notification has been acquired (S71). "YES" in S71) The expansion process is started.

  If there is no actual information developed in each functional unit area of the second process data storage unit 622 when the expansion process is started (“NO” in S72), the information is stored in the second synchronization area storage unit 624. Is expanded in the corresponding function part of the corresponding session information area of the second processing data storage part 622 (S73).

  Next, the information updated in the second synchronization area storage unit 624 is acquired in the second processing data storage unit 622 (S74). This process is repeated until all updated information is obtained.

  Then, the information developed in the second processing data storage unit 622 in step S73 or the information already developed as determined in “YES” in step S72 is updated and developed with the update information acquired in step S74. (S75). When the update process of the second process data storage unit 622 is completed, a transfer process completion notification is transmitted from the second synchronization area storage unit 624 to the ACT (active) call control server 61.

  As described above, (ii) the information stored in the second synchronization area storage unit 624 is expanded in the second processing data storage unit 622 at the expansion timing based on event driven, and is sequentially updated to the latest information. The second processing data storage unit 622 of the system call control server 62 is surely expanded with the same information as the information expanded in the first processing data storage unit 612 of the ACT (active) system call control server 61. Can do.

  As described above, the information developed in the first processing data storage unit 612 of the ACT (active) call control server 61 at (i) the deployment timing based on polling or (ii) the deployment timing based on event-driven The same information is expanded in the second processing data storage unit 622 of the SBY (standby) system call control server 62, so that the call control processing is performed from the ACT (active) system call control server 61 to SBY (standby). Since only untransferred information needs to be transferred when switching to the system call control server 62, the processing amount can be reduced and the system switching processing time can be shortened.

  In addition, even if a failure occurs in the ACT (active system) call control server 61, it is possible to prevent a call from being disconnected at a timing unintended by the user and to execute an efficient process, and to provide a high-quality communication service. Can be provided.

  In the above embodiment, when it is determined that the sequence pattern being processed by the sequence function unit 6115 has been completed to the end, the service function unit 6116 is further notified of the sequence pattern information held as being processed by the sequence function unit 6115. The memory part is freed. In addition, when notified that the processing of the sequence pattern being processed by the sequence function unit 6115 has been completed, the service function unit 6116 that has been notified manages according to the service contents subscribed by the corresponding calling / receiving subscriber terminal 2. The sequence pattern to be executed next is specified based on the existing scenario, and the sequence pattern to be used next is instructed to the sequence function unit 6115.

  In the above embodiment, the communication established by the call control system 6 is used, and the SDP information is used between the subscriber terminal of the information source and the media servers 7A and 7B via the relay servers 5A and 5B. Then, media information such as audio information and video information may be transferred, and such information may be provided to the subscriber terminal.

  In the above embodiment, when the call disconnection sequence is executed, the destination information held in the UAC 6114b of the UA function unit 6114 and the sequence pattern information held in the sequence function unit 6115 are included in this sequence. The relevant part of the memory is released and deleted (invalidated). Release may be done by setting a timer. As an effect of releasing after setting the timer, even when a signal such as BYE is retransmitted, it is possible to correctly process the signal within a certain period.

  This example is a communication example in which the calling side and the called side are on a one-to-one basis, but this is also applicable to calls with a plurality of people such as a three-party call such as a telephone conference service. In the case of a three-party call, the service function unit 6116 refers to the service scenario at the time of calling and instructs the sequence function unit 6115 to use the sequence pattern for the three parties. Upon receiving the instruction, the sequence function unit 6115 reads the sequence pattern for the three parties and instructs the UA function unit 6114 to generate the UA for the three parties. Upon receiving the instruction, the UA function unit 6114 generates three UAs (one UAS and two UACs). Subsequent signal processing is performed as shown in the previous example. In this way, a complicated sequence pattern can be realized without changing the function section.

  Further, in the call control system of the present embodiment, the relief data is obtained by synchronizing the information between the previous ACT (active) call control server 61 and the SBY (standby) call control server 62 (relief data transfer process). Even if the information of subsequent changes is lost, it is set to transfer at the timing when the call control processing can be recovered according to the protocol, so it is only necessary to transfer only untransferred data instead of all data at the time of system switching. Therefore, the system switching time can be shortened.

  In addition, since the storage units of the ACT (active) call control server and the SBY (standby) call control server constructed in the present embodiment are each provided with a spare area, a new service is added or a protocol is changed. When the amount of information is expanded such as when the data size is changed, the spare area can be effectively used to flexibly cope with the expansion.

  As an advantage of this method, since the call control server has separate processing units for incoming and outgoing calls and manages the data, it does not transfer data uniformly at the timing of sending and receiving the specified signal, but sets the relief timing when sending and receiving each connection. It is possible to set flexibly and efficiently synchronize the information of the ACT server and the information of the SBY server. In addition, when considering a service between three or more parties including a media server in addition to a telephone terminal, a user agent function unit, a protocol function unit, a transport is provided in the call control server corresponding to each terminal or media server. By generating a function unit and preparing a scenario and a sequence pattern according to the service, it is possible to cope without changing the function unit of the call control server, and the same effect as the service example between the two parties can be obtained.

DESCRIPTION OF SYMBOLS 1 ... SIP communication system 2A-2D ... Subscriber terminal 3 ... IP network 3A-3G ... Transfer apparatus 4A, 4B ... SIP server 5A, 5B ... Relay server 6 ... Call control system 7A, 7B ... Media server 61 ... ACT (current use) ) System call control server 62 ... SBY (standby) system call control server 611 ... 1st call processing control unit 612 ... 1st processing data storage unit 612A ... 1st session information area 612B ... 2nd session information area 612C ... 3rd Session information area 613 ... 1st synchronization processing control part 614 ... 1st synchronization area storage part 614A ... 1st session information area 614B ... 2nd session information area 614C ... 3rd session information area 621 ... 2nd call processing control part 622 ... Second processing data storage unit 622A ... first session information area 622B ... second session information Area 622C ... third session information area 623 ... second synchronization processing control section 624 ... second synchronization area storage section 624A ... first session information area 624B ... second session information area 624C ... third session information area 6111 ... transport function Unit 6111a ... reception processing unit 6111b ... transmission processing unit 6112 ... reception signal buffer 6113 ... protocol function unit 6113a ... reception processing unit 6113b ... transmission processing unit 6114 ... UA (user agent) function unit 6114a ... UAS
6114b ... UAC
6115 ... Sequence function unit 6116 ... Service function unit 6117 ... Transmission signal buffer

Claims (3)

An active call control server that controls call processing between a plurality of SIP servers that execute call processing, and a standby system that operates by switching to the active system when a failure occurs in this active call control server A call control system comprising a call control server,
The standby call control server stores information related to call processing being processed by the active call control server in a synchronization area storage unit within the server;
The active call control server transfers a change in information relating to call processing being processed by the own server to the standby call control server at a predetermined transfer timing;
The standby call control server stores the change in the information related to the call processing being processed transferred from the active call control server by the synchronization processing control unit in its own server stored in the synchronization area storage unit. Updating the information;
When the processing data storage unit in the standby call control server detects that the information stored in the synchronization area storage unit has been updated, the updated information is acquired from the synchronization area storage unit. Expanding to an area in the processing data storage unit for use in call processing when the server is in operation;
A method for redundancy of information used for call control, comprising: In the processing data storage unit of the standby call control server,
As a result of confirming whether or not information is updated in the synchronization area storage unit at a predetermined time interval, when it is detected that the information stored in the synchronization area storage unit has been updated, or update is performed from the synchronization area storage unit When it is detected that the information stored in the synchronization area storage unit has been updated due to the notification that there has been, the updated information is acquired from the synchronization area storage unit and stored in the processing data storage unit The information redundancy method for call control according to claim 1, wherein the information is used for call control. An active call control server that controls call processing between a plurality of SIP servers that execute call processing, and a standby system that operates by switching to the active system when a failure occurs in this active call control server A call control system comprising a call control server,
The active call control server is:
Having a synchronous processing control unit for transferring a change in information relating to call processing being processed by the own server to the standby call control server at a predetermined transfer timing;
The standby call control server is:
Synchronous area storage for storing information relating to call processing being processed by the active call control server, and updating the stored information with changes in information relating to the call processing being processed transferred from the active call control server And
When it is detected that the information stored in the synchronization area storage unit has been updated, the updated information is acquired from the synchronization area storage unit and used in call processing when the local server operates. A processing data storage unit that expands in the area of
A call control system.

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