JP4916670B2 - IP phone system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a highly reliable IP telephone system capable of continuously operating the system even if a failure occurs in one main control unit (CC) and one signal control unit (SC) by duplexing the main control unit (CC) of an IP exchange unit (TM) and providing a backup SC for each of a plurality of signal processing units (SC). <P>SOLUTION: The system is provided with a duplex main control unit 3 having a main control unit 3a of an acting system (ACT system) and a main control unit 3b of a standby system (SBY system), and a signal control unit (SC)4 in which N+1 redundancy is applied to SC-0 to SC-7 and a backup SC-0. <P>COPYRIGHT: (C)2006,JPO&amp;NCIPI

Description

  The present invention relates to an IP telephone system that centrally manages and operates all IP terminals installed at each base, and in particular, duplication of a main controller constituting an IP exchange and N + 1 redundancy of a signal controller. The present invention relates to an IP telephone system that doubles a line and provides a backup exchange at each base to perform backup for an apparatus failure or a line failure and improve the reliability of system operation.

  In a conventional exchange, an IP call control unit (SC unit) that performs call control of an IP terminal via a line (network) such as a LAN, and an exchange control unit that performs data exchange control of the IP call control unit (SC unit) An IP exchange (TM unit) including a CC unit) and accommodating an IP terminal via a HUB is disclosed (for example, Patent Document 1).

The IP exchange (TM unit) configured in this manner can be equipped with a plurality of IP call control units (SC units) according to the connection processing capability (number of IP terminals) of the accommodated IP terminals.
JP 2004-229112 A

  Since the conventional IP switch (TM) has a single switching control unit (CC unit), when a failure occurs in the IP call control unit (SC unit), there are many in each of the plurality of IP call control units (SC units). In the case where an IP telephone system is configured by accommodating such IP terminals, the entire system may be down.

  Further, assuming that a plurality of IP terminals are accommodated in a plurality of IP call control units (SC units), and a base having a plurality of IP terminals is provided for each IP call control unit (SC unit), IP If the call control unit (SC unit) breaks down, operation of the base in charge of this IP call control unit (SC unit) becomes impossible.

  The present invention has been made to solve such problems, and its purpose is to duplicate the main controller (CC) of the IP exchange (TM) and to provide backup SCs for a plurality of signal controllers (SC). An object of the present invention is to provide a highly reliable IP telephone system capable of continuing system operation even if a failure occurs in one main control unit (CC) and one signal control unit (SC).

In order to solve the above problems, an IP telephone system according to the present invention accommodates a plurality of IP terminals for each site via a line under the control of a main controller that controls the overall operation of the IP exchange, and the main controller. A center IP switch equipped with a plurality of signal control devices for control, a line connecting the IP switch and the base, a backup switch that detects a failure of the IP switch or a line fault, and backs up the base In an IP telephone system comprising a plurality of bases equipped with a plurality of IP terminals and managing / operating all the IP terminals centrally with an IP exchange, one of the plurality of signal control devices includes an IP terminal It is a spare signal control device that is not accommodated, and the main control device sets a different IP address to a plurality of signal control devices, and if a failure occurs in one signal control device, the spare signal control device The IP address of the control device is changed to the IP address of the signal control device in which the failure has occurred, and control is performed to switch the signal control device in which the failure has occurred to the spare signal control device. to take over the IP address of the IP terminal which has been accommodated in the signal control apparatus, and executes up balls continue the call a call control.

  The main control device according to the present invention sets an IP address in a plurality of signal control devices, and when a failure occurs in one signal control device, the signal control device in which the failure occurs in the IP address of the spare signal control device Control to switch the failed signal control device to the spare signal control device, so even if the active signal control device fails, switch to the spare signal control device and continue operation can do. Further, the main control device according to the present invention sets an IP address in a plurality of signal control devices, and when a failure occurs in one signal control device, the signal in which the failure occurs in the IP address of the spare signal control device By changing to the IP address of the control device, the backup exchange and the IP terminal controlled by the signal control device in which the failure has occurred need not re-login, for example, without disconnecting the call even during a call. The operation can be continued (backed up) by the spare signal control device (while the call is continued).

  In addition, the main control device according to the present invention is characterized in that a communication check is performed with a plurality of signal control devices, and it is determined that there is a failure when the communication check of the corresponding signal control device cannot be performed.

  The main control device according to the present invention performs communication confirmation with a plurality of signal control devices, and determines that there is a failure when communication confirmation of the corresponding signal control device cannot be performed. The detection can be executed without the communication confirmation.

  Furthermore, the main control device according to the present invention is characterized in that, when switching to a spare signal control device, the minimum initial condition is checked and the switching time is shortened.

  When the main control device according to the present invention switches to a spare signal control device, the minimum initial condition is checked and the switching time is shortened. You can switch to

  The main control device according to the present invention has a duplex configuration of an active system and a standby system. The standby system captures and stores call control information of the active system, and when the active system fails, the standby system It is characterized by operating as an operational system.

  The main control device according to the present invention has a duplex configuration of an active system and a standby system. The standby system captures and stores the call control information of the active system, and operates the standby system when the active system fails. Since the system operates as a system, even if the operating system fails, the system can be operated continuously without going down.

  The main control device according to the present invention sets an IP address in a plurality of signal control devices, and when a failure occurs in one signal control device, the signal control device in which the failure occurs in the IP address of the spare signal control device Control to switch the failed signal control device to the spare signal control device, so even if the active signal control device fails, switch to the spare signal control device and continue operation It is possible to improve the reliability of system operation.

  Further, the main control device according to the present invention performs communication confirmation with a plurality of signal control devices, and determines that a failure occurs when communication confirmation of the corresponding signal control device cannot be performed. Failure detection can be executed without the communication confirmation, and the signal control device in operation can be easily determined.

  Further, when the main control device according to the present invention switches to a spare signal control device, the minimum initial condition is checked and the switching time is shortened. The system can be switched to the control device, and the system operation can be continued.

  The main control device according to the present invention has a duplex configuration of an active system and a standby system. The standby system captures and stores call control information of the active system, and when the active system fails, the standby system Therefore, even if the operation system fails, the system can be operated continuously without going down, and the high reliability of the system can be appealed.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. The IP telephone system of the present invention has a head office and a head office, such as a large-scale business entity, for example, a mega bank, has branch offices and branch offices, and has an IP exchange set up with the head office as a center. This is applicable to many bases where multiple IP terminals are installed at each base for business activities. All IP terminals installed at all bases are connected to a line (such as a WAN (Wide Area LAN)). The network is housed in the center IP switch and the call control of all IP terminals is executed by the center IP switch, thereby centrally managing calls between all the IP terminals.

  In addition, the IP telephone system of the present invention increases the reliability of the system by providing redundancy and duplication of devices and lines (networks) in the system and backing up against failures and failures. is there.

  FIG. 1 is a block diagram of an embodiment of an IP telephone system according to the present invention. In FIG. 1, an IP telephone system 1 includes an IP exchange 2 installed in a center, a backup exchange (B-TM) 6 installed in each of the bases A1 to Hn, a plurality of IP terminals Eqi, It is constructed from a line (network) 5 such as a WAN connecting the IP exchange 2 and all the bases A1 to Hn.

  The IP exchange (TM) 2 includes a main control device (CC) 3 that controls the overall operation of the IP exchange (TM) 2 and a base A 1 via a line (network) 5 under the control of the main control device (CC) 3. A plurality of signal control devices 4 that accommodates a plurality of IP terminals Eqi installed for each Hn and perform call control are provided.

  The signal control device 4 is composed of SC-0 to SC-7 and SC-N (backup SC) connected to the main control device (CC) 3 via the control bus BU. SC-0 to SC-7 are The IP terminals Eqi of the bases A1 to Hn are accommodated via the line (network) 5 and call control of the IP terminals Eqi is executed. In addition, when SC-0 to SC-7 are normal, SC-N (backup SC) does not accommodate any IP terminal Eqi at base A1 to base Hn, and one of SC-0 to SC-7 has failed. In this case, the failed SC-0 to SC-7 are backed up, and the IP terminals Eqi of the corresponding bases A1 to Hn are accommodated.

  The base A is composed of the base A1 to the base An, the base B is composed of the base B1 to the base Bn, ..., the base H is composed of the base H1 to the base Hn, and the bases A1 to Hn are respectively relayed. Connect to the line (network) 5 via the network.

  The IP terminals Eqi of the bases A1 to Hn are accommodated in SC-0 to SC-7 by logging in to SC-0 to SC-7, respectively, at the time of activation.

  The backup exchange (B-TM) 6 is connected to the LAN (Local Area Network) of the bases A1 to Hn, and the backup exchange (B-TM) 6A1 and the backup exchange (B -TM) 6A2, ..., backup exchange (B-TM) 6Hn, and when the IP exchange 2 is operating normally, it is in a standby state (standby system) and does not perform call control of the IP terminal Eqi.

  Further, the backup exchange (B-TM) 6A1, the backup exchange (B-TM) 6A2,..., The backup exchange (B-TM) 6Hn are in an operational state (active system) when a failure occurs in the connected relay network. In place of the corresponding SC-0 to SC-7n, the login from the IP terminal Eqi is accepted and the call control of the IP terminal Eqi is performed, so that the communication between the IP terminals Eqi in the bases A1 to Hn is possible. To do.

  The IP telephone system 1 is composed of, for example, 8 units SC-0 to SC-7, each SC-0 to SC-7 covers 16 bases, and one SC has a total of 16 bases. A large-scale system is assumed that can accommodate 2000 IP terminals Eqi and one system can accommodate 16000 IP terminals Eqi.

  FIG. 2 is a connection diagram of the embodiment of the main controller and the signal controller according to the present invention. In FIG. 2, the main control device (CC) 3 has a double configuration, and includes an operation (ACT) main control device 3 a and a standby (SBY) main control device 3 b.

  The main controller 3a of the active system (ACT system) is connected to SC-0 to SC-7 and SC-N (backup SC) constituting the signal control apparatus 4 via the control bus BU-a, and is connected to the standby system (backup SC). The main controller 3b (SBY system) is connected to SC-0 to SC-7 and SC-N (backup SC) via a control bus BU-b.

  SC-0 to SC-7 and the backup SC are connected to both the control bus BU-a and the control bus BU-, and are connected to the main controller 3a of the operation system (ACT system) via the control bus BU-a. Then, it is connected to the standby (SBY) main controller 3b via the control bus BU-b.

  The main control unit 3a of the active system (ACT system) includes a CPU-a and a RAM-a, and has an IP address a to an IP address h and an IP address i of SC-0 to SC-7 and SC-N (backup SC). And call processing information such as station data is stored, and SC-0 to SC-7 and SC-N (backup SC) are controlled via the control bus BU-a.

  The standby system (SBY system) main control device 3b includes a CPU-b and a RAM-b, and the operation system (ACT system) main control device 3a is always in operation when operating (ACT system) main control device. 3a is monitored, and when a failure of the main control device 3a is detected, the main control device 3a is switched to switch from the standby system (SBY system) to the active system (ACT system) to control bus BU-b. SC-0 to SC-7 and SC-N (backup SC) are controlled via

  The active (ACT) main controller 3a stores the call control information in the RAM-a and at the same time, also stores it in the RAM-b of the standby (SBY) main controller 3b. In the event of a failure, the switching to the main control device 3b is quickly shifted.

  Thus, the main controller (CC) 3 according to the present invention has a duplex configuration of the active system (main controller 3a) and the standby system (main controller 3b), and the standby system (main controller 3b) Since the call control information of the active system (main control device 3a) is captured and stored, and the active system (main control device 3a) fails, the standby system (main control device 3b) operates as the active system. Even if the operation system fails, the system can be operated continuously without going down, and the high reliability of the system can be appealed.

  Main controller (CC) 3 sets IP address a to IP address h and IP address i in SC-0 to SC-7 and SC-7 (backup SC) constituting signal controller 4. For example, SC-0 has an IP address a, SC-1 has an IP address b, SC-2 has an IP address c, SC-3 has an IP address d, SC-4 has an IP address e, SC-5 has an IP address f, The IP address g is initially set in SC-6, the IP address h is set in SC-7, and the IP address i is initialized in SC-N (backup SC). IP addresses a to h can be arbitrarily set to SC-0 to SC-7 and SC-7 (backup SC).

  Further, the main controller (CC) 3 always confirms communication with SC-0 to SC-7 and SC-N (backup SC). For example, when communication confirmation of SC-0 cannot be performed, SC-0 Is determined to be faulty.

  Further, when the main controller (CC) 3 determines that SC-0 is a failure, it changes the IP address i of SC-N (backup SC) to the IP address a of SC-0 where the failure occurred, and a failure occurs. The control for switching the SC-0 to SC-N (backup SC) is executed.

  The signal control unit (SC) 4 is composed of SC-0 to SC-7 and SC-7 (backup SC), each of which is an interface with the main control unit (CC) 3, CCI / F, and control unit (CPU). A maintenance unit for detecting and notifying a failure, a LAN port serving as an interface with the line (network) 5, and the like.

  The SC-0 to SC-7 of the signal control device (SC) 4 are configured with the IP address a to IP address h from the main control device (CC) 3 to form the operational system, and the IP for each of the sites A to H IP terminals from the terminal Eqi are login destinations based on the IP address a to IP address h, and by receiving the IP address of the IP terminal Eqi for each of the logged-in bases A to H, the IP terminals for the bases A to H respectively. Contains Eqi.

  The SC-N (backup SC) of the signal control device (SC) 4 is set with the IP address i from the main control device (CC) 3 to form a standby system (backup system). The terminal Eqi is not accommodated at all.

  When a failure occurs in one of SC-0 to SC-7 (for example, SC-0), the IP address i of SC-N (backup SC) is SC-0 under the control of the main controller (CC) 3. After being changed to the IP address a, the SC-N (backup SC) switches from the standby system to the active system as SC-0.

  At this time, the SC-N (backup SC) takes over the IP address of the IP terminal Eqi logged in to SC-0, accommodates and operates the IP terminal Eqi of the base A, and calls the IP terminal Eqi of the base A. Control will be executed continuously.

  On the other hand, after the repair, the SC-0 that has failed is set to the SC-N (backup SC) with the IP address i under the control of the main controller (CC) 3, and then goes to the standby system. This corresponds to the failure of the operational SC-0 to SC-7.

  After the repair, the SC-0 in which the failure has occurred is controlled by the main control unit (CC) 3 to control the IP address a and the IP terminal Eqi of the base A from the operating SC-0 (previous backup SC). It is also possible to take over the IP address, start operation again as SC-0, set the IP address i to the operating SC-0 (previous backup SC), and return to the SC-N (backup SC). .

  FIG. 3 is an explanatory view of an embodiment of switching of the signal control device according to the present invention. In FIG. 3, SC-0 to SC-7 constituting the signal control device 4 are operating with IP address a to IP address h, respectively, and IP terminals of site A to site H via line (network) 5. Eqi is accommodated and call control of the IP terminal Eqi is performed.

  On the other hand, the SC-N (backup SC) is waiting at the IP address i, but can accommodate the IP terminal Eqi at any one of the bases A to H.

  SC-0 to SC-7 and SC-7 (backup SC) check communication with the main control unit (CC) 3 for normal operation monitoring (indicated by broken lines).

  If one of the operating SC-0 to SC-7 (for example, SC-0) fails, the communication between the main controller (CC) 3 and SC-0 cannot be confirmed, and the main control When the device (CC) 3 detects the SC-0 failure, the device (CC) 3 changes the IP address i of the SC-N (backup SC) to the IP address a of the SC-0 where the failure occurred, and the SC-0 where the failure occurred. And SC-N (backup SC) are switched to operate SC-N (backup SC) as SC-0.

  The main controller (CC) 3 only checks (reboots) the minimum initial conditions necessary for the operation of the SC-N (backup SC) when switching between SC-0 and SC-N (backup SC). In order to execute the switching, the switching time is shortened to minimize the influence of switching between SC-0 and SC-N (backup SC), and the operation of SC-0 is continued.

  As described above, when switching to the spare signal control device (backup SC), the main control device (CC) 3 according to the present invention checks the minimum initial conditions and shortens the switching time. The signal control device 4 (SC-0) can be switched to the spare signal control device 4 (SC-N) in the shortest time, and the system operation can be continued.

  FIG. 4 is a communication confirmation operation sequence diagram of an embodiment of a signal control apparatus according to the present invention. In FIG. 4, SC-0 to SC-7 during operation of the signal control device (SC) 4 indicate a normal state. Communication is confirmed between the main controller (CC) 3 and SC-0 to SC-7 and SC-N (backup SC).

  Main controller (CC) 3 transmits a communication test to SC-0 to SC-7 and SC-N (backup SC), and is transmitted from SC-0 to SC-7 and SC-N (backup SC). By receiving the coming communication test result, it is determined that no failure has occurred in SC-0 to SC-7 and SC-N (backup SC).

  FIG. 5 is a communication confirmation operation sequence diagram of another embodiment of the signal control apparatus according to the present invention. FIG. 5 shows a case where a failure (failure) has occurred in the active signal control device 4 (SC-0). In this state, no matter how many times the communication test is transmitted from the main controller (CC) 3 to the SC-0, the main controller (CC) 3 cannot receive the communication test result from the SC-0. The communication confirmation between the main controller (CC) 3 and SC-0 is eliminated.

  The main controller (CC) 3 determines that SC-0 is faulty (failure), and switches SC-N (backup SC) to SC-0 in which the fault has occurred. The SC-N (backup SC) reboots (restarts), and transmits an SC initial request to the main controller (CC) 3.

  When the main control unit (CC) 3 receives the SC initial request from the SC-N (backup SC), the main control unit (CC) 3 transmits the minimum initial setting information to the SC-N (backup SC). The backup SC) is started to operate as SC-0.

  As described above, the main controller (CC) 3 according to the present invention confirms communication with the plurality of signal controllers (SC) 4 and confirms communication with the corresponding signal controller (for example, SC-0). If it is not possible, it is determined that there is a failure. Therefore, the failure detection of the operating signal control device can be executed without confirmation of communication, and the operating signal control device can be easily determined.

  FIG. 6 is a switching operation sequence diagram of an embodiment of a signal control apparatus according to the present invention. In FIG. 6, a failure occurs in SC-0, and thereafter, a recovery process is performed to operate as a backup SC. On the other hand, the backup SC switches to SC-0 and operates as an active system when a failure occurs in SC-0.

  In this state, when an SC switching command is executed by the main controller (CC) 3 and an SC switching processing command is transmitted to both the SC-0 and the backup SC, SC-0 (standby as a backup SC) And the backup SC (operating as SC-0) reboots, SC-0 switches back to the SC-0 (active system) before the failure (failure), and the backup SC (backup standby before the failure (failure) occurs) Return to System).

  As described above, the main controller (CC) 3 according to the present invention sets IP addresses (IP addresses a to i) to the plurality of signal controllers 4 (SC-0 to SC-7 and SC-N), When a failure occurs in one signal control device (SC-0), the IP address i of the spare signal control device (SC-N) is set to the IP address a of the signal control device (SC-0) where the failure has occurred. Since the control is performed to switch the signal control device (SC-0) in which the failure occurs to the spare signal control device (SC-N), even if the signal control device in operation fails, the spare signal control device The operation can be continued by switching to, and the reliability of system operation can be improved.

  Next, duplexing of the LAN port of the signal control apparatus according to the present invention will be described. SC-0 to SC-7 and SC-N (backup SC) constituting the signal control device 4 are respectively two LAN ports, an A-system port PHY0 of the active system and a B-system port PHY1 of the standby system, and 2 A CPU for controlling switching of the LAN port of the system is provided.

  The A system port PHY0 is connected to the A system network of the two lines (network) 5 via the LAN, and the B system port PHY1 is connected to the B system network of the two systems (network) 5 via the LAN. To do.

  A GW (gateway) 7a is connected to the A-system network, and a GW (gateway) 7b is connected to the B-system network.

  SC-0 to SC-7 and SC-N (backup SC) are connected to the main control unit (CC) 3 via the control bus BU, and send a layer 1 fault occurrence notification and a fault recovery notification to the main control unit ( CC) 3.

  When a failure occurs in the A-system port PHY0 connected to the A-system network of the signal control device 4 (for example, SC-0), a failure notification is sent from the CPU to the main control device (CC) 3, and the A-system port The operation is continued by switching from PHY0 to the B-system port PHY1 and connecting to the B-system network.

  If a layer 1 failure occurs while the A-system port PHY0 is operating (operating), the IP address and MAC address of the A-system port PHY0 are transferred to the B-system port PHY1, and switched to the B-system port PHY1 to operate (operate). The A system port PHY0 is backed up by the B system port PHY1.

  FIG. 7 is an explanatory diagram of port switching according to an embodiment of the signal control apparatus according to the present invention. In FIG. 7, the signal control device 4 is composed of SC-0 to SC-7 and SC-N (backup SC), and each A system port PHY0 (operating system) connected to the A system network of the line (network) 5. And a B-system port PHY1 (standby system) connected to the B-system network.

  When a layer 1 failure is detected while the A-system port PHY0 (active system) is operating, the CPU switches the A-system port PHY0 to the B-system port PHY1 (solid line display → broken line display) to make the active system B Call control of the IP terminals Eqi of the corresponding bases A to H is executed from the PHY 1 via the B-system network.

  On the other hand, when the Layer 1 failure of the A-system port PHY0 is restored, the B-system port PHY1 is switched to the A-system port PHY0 (broken line display → solid line display) under the control of the CPU and switched back to the active system, or the B-system port Let PHY1 be the active system without switching back, and the A-system port PHY0 be the standby system.

  FIG. 8 is a switching sequence diagram of an embodiment of a LAN port according to the present invention. In FIG. 8, when a layer 1 failure occurs during operation on the A-system port PHY0, the maintenance unit sends an A-system layer 1 failure occurrence notification to the CCI / F, and the CCI / F is in the B-system link-up state. And sends an instruction to switch to the B-system port PHY1 in a packet to the B-system port PHY1.

  The LAN port that has received the packet from the CCI / F is switched from the A-system port (A-system port PHY0) to the B-system port (B-system port PHY1), and operates on the B-system port.

  On the other hand, even if an A system layer 1 failure recovery notification is sent from the maintenance unit to the CCI / F while operating on the B system port PHY1, the CCI / F does not switch back the A system port PHY0, and the LAN port The operation operation is continued at the B system port PHY1.

  FIG. 9 is a switching sequence diagram of another embodiment of the LAN port according to the present invention. In FIG. 9, a layer 1 failure occurs at the A-system port PHY0, and the LAN port is switched from the A-system port (A-system port PHY0) to the B-system port (B-system port PHY1) until operation is performed at the B-system port. It is the same as FIG.

  When an A-system layer 1 failure recovery notification is sent from the maintenance unit to the CCI / F while operating on the B-system port PHY1, the CCI / F switches back to the A-system port PHY0 and sends it to the A-system port PHY0. The switching instruction is sent to the A-system port PHY0 as a packet, and the LAN port switches from the B-system port (B-system port PHY1) to the A-system port (A-system port PHY0) (switches back), and operates on the A-system port. To do.

  Next, the base backup switch according to the present invention will be described. Each base of the IP telephone system includes a backup switch 6 (backup switch 6A1-6Hn shown in FIG. 1) for each base (bases A1-Hn shown in FIG. 1).

  The backup switch (B-TM) 6 is in a standby state (standby system) except for a unicast-multicast conversion operation described later in a normal operation state in which there is no failure in the IP switch (TM) 2 or the line (network) 5. ) And confirming communication with the signal control device (SC) 4 (SC-0 to SC-7) of the IP switch 2 to which each belongs.

  Further, the backup switch (B-TM) 6 is also in a no-care state for a plurality of IP terminals Eqi belonging to a base to which the backup switch (B-TM) 6 belongs (for example, the base A).

  Further, the backup exchange (B-TM) 6 switches from the standby state (standby system) to the operational state (active system) when the failure of the IP exchange (TM) 2 or the line (network) 5 is abnormal. The extension call of the IP terminal Eqi is backed up.

  Switching from the standby state (standby system) to the operational state (active system) confirms communication from the IP switch 2 (signal control device 4) due to a failure in the IP switch (TM) 2 or a failure in the line (network) 5 Execute if you cannot.

  On the other hand, the return from the operating state (active system) to the standby state (standby system) restores the failure of the IP switch (TM) 2 or the failure of the line (network) 5 and the IP switch 2 (signal control device 4). ) Is executed when the communication confirmation from) is resumed.

  The backup switch (B-TM) 6 enters an operational state (active system) when the failure of the IP switch (TM) 2 or the failure of the line (network) 5 occurs, and is logged in from the IP terminal Eqi in the base. An IP address is received, and call control is performed for extension calls between all IP terminals Eqi in the corresponding base (for example, base A).

  Further, the backup switch (B-TM) 6 switches back to the standby state (standby system) when the failure of the IP switch (TM) 2 or the failure of the line (network) 5 is recovered, and in the base (for example, the base A). All the IP terminals Eqi are logged out, and the call control of the extension call between all the IP terminals Eqi in the corresponding base (for example, the base A) is stopped.

  All the IP terminals Eqi in the base send an IP address to the IP switch 2 (signal control device 4) when the backup switch 6 is in the standby state and the IP switch (TM) 2 or the line (network) 5 is normal. Log in and make a call under the control of the IP exchange 2 (signal control device 4).

  Also, all IP terminals Eqi in the base log out from the IP switch 2 (signal control device 4) and back up when the IP switch (TM) 2 or the line (network) 5 in which the backup switch 6 becomes the active system is abnormal. An IP address is transmitted to the exchange 6 to log in, and an extension call within the base is performed under the control of the backup exchange 6.

  Further, all the IP terminals Eqi in the base log out from the backup switch 6 when the backup switch 6 returns to the standby system and recovers from an abnormality in the line (network) 5, and the IP switch 2 ( The IP address is transmitted to the signal control device 4) to log in, and a call in the system is performed under the control of the IP exchange 2 (signal control device 4).

  The IP terminal Eqi monitors the life check from the IP switch 2 (signal control device 4). When there is no life check and the time is over, the IP terminal Eqi logs out from the IP switch 2 (signal control device 4), and the backup switch 6 Send an IP address to and login.

  Further, the IP terminal Eqi monitors the life check from the backup exchange 6, and when there is no life check and the time is over, the IP terminal Eqi logs out from the backup exchange 6 and sends an IP address to the IP exchange 2 (signal control device 4). And log in.

  FIG. 10 is an operation schematic diagram of one embodiment of the backup exchange according to the present invention. In FIG. 10, the backup switch 6 (backup TM) of the base A, base B,..., Base N is accommodated in the center IP switch (TM) 2 via the line (network) 5. A plurality of IP terminals Eqi exist in each of the base A, the base B,.

  When the IP switch (TM) 2 and the line (network) 5 are normal without any trouble, all the IP terminals Eqi in the base A, base B,..., Base N send IP addresses to the IP switch (TM) 2. Log in and perform a call between all the IP terminals Eqi under the control of the IP exchange (TM) 2.

  When a failure occurs in the IP exchange (TM) 2 in the first case from when the system is normal, all the backup exchanges 6 (backup TM) in the base A, base B,. The system switches from the system to the operational system, and all IP terminals Eqi in the base A, base B,..., Base N also log out from the IP switch (TM) 2 and each IP address is sent to the backup switch 6 (backup TM) in their own base. Is transmitted and logged in, and the extension call within the local site becomes possible by the control of the backup switch 6 (backup TM).

  Also, in the second case, when a failure occurs in the network to which the base A is connected in the second case, the backup switch 6 (backup TM) at the base A switches from the standby system to the active system, and the base All the IP terminals Eqi of A log out from the IP exchange (TM) 2, log in by sending an IP address to the backup exchange 6 (backup TM) in the base A, and control of the backup exchange 6 (backup TM) An extension call within the base A can be made.

  On the other hand, all the IP terminals Eqi in the base B,..., Make a call between all the IP terminals Eqi in the base B,..., N under the control of the IP exchange (TM) 2. Note that when an abnormality occurs in the IP exchange (TM) 2 and the network at the same time, the same phenomenon as in the first case occurs.

  Next, the sequence operation of the backup exchange at the site according to the present invention will be described. The backup switch 6 (backup TM) at each site has an operation sequence for switching from the standby state to the operation state and an operation sequence for switching from the operation state to the standby state.

  FIG. 11 is an operation sequence diagram from the standby system to the active system according to the embodiment of the backup exchange according to the present invention. The operation sequence is as follows: the backup exchange 6 at the base A (backup TM-A) and the IP terminal Eqi (terminal A), the IP exchange (TM) 2 at the center, and the backup exchange 6 at the base B (backup TM-B). The mutual connection between the IP terminals Eqi (terminal B) will be described.

  When the center TM and the network are normal, the terminal A at the base A and the terminal B at the base B are “TM login operation” at the center respectively, and the terminal A and the terminal B perform “call control” with the TM. "Message" (dial transmission, transfer, incoming call, etc.) is exchanged, "life check" from TM is monitored, and "life check response" is sent to TM.

  On the other hand, the backup TM-A at site A and the backup TM-B at site B are “operating in the standby system” and send an “operation ready notification (preliminary system display)” to the TM. By receiving the “notification (operation system display)”, the communication confirmation between the backup TM-A and the TM at the base A and between the backup TM-B and the TM at the base B is executed.

  From this state, if a failure occurs in the relay network (network) connecting the TM and the base B, the backup TM-B at the base B cannot receive the “operation ready notification (operation system display)” from the TM at the center. Since “TM communication disconnection detection” is to be performed, “switch to operational operation” is executed.

  On the other hand, the terminal B at the base B cannot receive the “life check” from the center TM, performs “life check timeout detection”, “logs out from the TM”, and then sets “backup TM-B as the login destination”. By “login”, the backup TM-B at the base B accepts “login of the terminal B”.

  At this point, the center TM detects “terminal B life check NG” and recognizes “terminal B logout”.

  When the backup TM-B at the base B that has become the active system accepts “login of terminal B”, terminal B becomes “logging in to backup TM-B”, and “ Control messages "(dial transmission, transfer, incoming call, etc.) are exchanged, and extension calls within the base B can be made.

  Thereafter, the terminal B monitors the “life check” from the backup TM-B and transmits a “life check response” to the backup TM-B.

  On the other hand, the backup TM-A and the terminal A at the base A where there is no failure in the relay network (network) are operating while the backup TM-A operates in the standby system and the terminal A logs into the TM.

  FIG. 12 is an operation sequence diagram from the active system to the standby system according to the embodiment of the backup exchange according to the present invention. As in FIG. 11, the operation sequence is similar to that of the backup exchange 6 (backup TM-A) at the base A, the IP terminal Eqi (terminal A), the IP exchange (TM) 2 at the center, and the backup exchange 6 at the base B ( A description will be given between the backup TM-B) and the IP terminal Eqi (terminal B).

  Further, the backup exchange 6 (backup TM-A) and the IP terminal Eqi (terminal A) at the base A have no trouble in the relay network (network) connecting the base A and the IP exchange (TM) 2 at the center. Therefore, the operation sequence is the same as that in FIG. 11, and the mutual operation between the backup exchange 6 (backup TM-B) at the base B, the IP terminal Eqi (terminal B), and the IP exchange (TM) 2 at the center will be described.

  Since a failure has occurred in the relay network (network) connecting the TM and the base B, the backup TM-B is “operating in the operation system”, and the terminal B is “logging in to the backup TM-B. Is.

  The terminal B exchanges “call control messages” (dial transmission, transfer, incoming call, etc.) with the backup TM-B, monitors the “life check” from the backup TM-B, Send life check response.

  From this state, when the failure of the relay network (network) connecting the TM and the site B is recovered, the backup TM-B at the site B receives an “operation ready notification (operation system display)” from the TM, By transmitting the “operation ready notification (operation system display)”, the communication confirmation between the backup TM-B and the TM at the base B is resumed, and “TM communication recovery detection” is performed.

  Subsequently, the backup TM-B at the site B switches back to “switch to standby operation” and executes “stop communication of login terminal (terminal B)”.

  Thereafter, the backup TM-B at the site B repeatedly receives the “operation ready notification (active system display)” from the TM and transmits the “operation ready notification (preliminary system display)” to the TM.

  On the other hand, when the backup TM-B switches back to the standby system, the terminal B cannot receive the life check from the backup TM-B, and when “life check timeout detection” is performed, “log out from the backup TM-B” “TM is set as the login destination”, “login” to the TM, and “login operation to TM” is performed. In this state, the terminal B at the site B can talk within the system.

  When the TM receives a login from the terminal B, the TM transmits a “life check” to the terminal B, receives a “life check response” from the terminal B, confirms normality, and performs “call control” with the terminal B. "Message" (dial transmission, transfer, incoming call, etc.) is exchanged and the terminal B's call is controlled.

  On the other hand, the backup TM-B receives an “operation ready notification (operation system display)” from the TM, and transmits a “operation ready notification (standby system display)” to the TM, thereby confirming communication with the TM. Execute.

  Next, a relay method for common message communication in the IP telephone system will be described. The IP telephone system 1 of the present invention assumes a large number of IP terminals Eqi installed at each base (for example, 16000 in the whole system), and sends a common message such as lamp information from the IP switch 2 to the base IP terminal. When sending to the base, specify the base to send the common message from the IP switch (TM) 2, send the common message to the base by unicast message, convert the unicast message to multicast message in the base, all A multicast message is transmitted to the IP terminal Eqi.

  FIG. 13 is a relay system diagram showing one embodiment of common message communication according to the present invention. A state in which the common message is transmitted as a multicast message (shown by a solid line) is also shown as a reference. In FIG. 13, the common message is sent from the main controller (CC) 3 of the IP exchange (TM) 2 to the signal controller 4 (SC-0 to SC-7) of the IP exchange (TM) 2 → the line (network) 5 → It is transmitted to the IP terminal Eqi in the base via the route of each base.

  First, when a common message is transmitted to all bases (all IP terminals Eqi of the system) as a multicast message (shown by a solid line), the main controller (CC) 3 to the signal controllers 4 (SC-0 to SC-7) In response to this, a multicast message is transmitted from the signal control apparatus 4 (SC-0 to SC-7) to all the bases via the line (network) 5 and from all the bases. A multicast message is transmitted to all IP terminals Eqi (not shown).

  Next, when the common message is transmitted to all the IP terminals Eqi at the base designated by the unicast message (displayed with a broken line), the main control device (CC) 3 to the signal control device 4 (for example, SC-0 and SC-7) selectively transmits a unicast message designating a destination (base), and bases 1 to 3 (designated from SC-0 and SC-7 via line (network) 5). A unicast message is transmitted to the control base of SC-0), base n to base n + 2 (control base of SC-7). Base 1 to base 3 and base n to base n + 2 convert the unicast message into a multicast message, and convert the converted multicast messages to all IP terminals Eqi (not shown) in base 1 to base 3 and base n to base n + 2, respectively. Send).

  The unicast message designating the transmission destination (base) is set by the main control device (CC) 3 based on the bitmap describing the transmission destination.

  In addition, since the base is designated, the data amount of the unicast message transmitted through the line (network) 5 can be reduced.

  The conversion from the unicast message to the multicast message is performed by the backup exchange 6 (multicast conversion apparatus = backup TM) and the IP-CONV (IP converter) 8 provided in the base, and the backup exchange 6 (multicast conversion apparatus = The multicast message is transmitted from the backup TM) or the IP-CONV (IP converter) 8 to all the IP terminals Eqi in the corresponding base.

  The backup exchange 6 (multicast conversion apparatus = backup TM) is connected to the operation system (A system) of the duplex line (network) 5 and the signal control apparatus 4 (SC-0 to SC-) in which the base is accommodated. 7) The unicast message transmitted from 7) is received, the unicast message is converted into a multicast message, and transmitted to the IP terminal Eqi in the base. Note that the backup switch 6 is a standby system when the active (A system) line is in operation, and operates as a multicast conversion apparatus that performs unicast-multicast conversion only when the backup switch 6 is in the standby system.

  The backup switch 6 (multicast conversion device = backup TM) is connected to the signal control device 4 (SC−) of the IP switch (TM) 2 in which the backup switch 6 (multicast conversion device = backup TM) is accommodated via the operation (A system) line (network) 5. 0 to SC-7).

  An IP-CONV (IP converter) 8 is connected to a standby system (B system) of a duplexed line (network) 5 and the backup switch 6 (multicast conversion apparatus = backup TM) fails or a line (network). ) Backs up the backup switch 6 and receives a unicast message transmitted from the signal control device 4 (SC-0 to SC-7) in which the base is accommodated in the case of failure of the operational system 5 (system A) Then, the unicast message is converted into a multicast message and transmitted to the IP terminal Eqi in the base.

  The IP-CONV (IP converter) 8 is connected to the signal control device 4 (SC-0 to SC) of the IP exchange (TM) 2 in which the device is accommodated via a standby (B system) line (network) 5. Confirm communication with -7).

  FIG. 14 is an explanatory diagram of unicast-multicast conversion according to an embodiment of the multicast conversion device (backup exchange) according to the present invention. In FIG. 14, the multicast conversion devices (backup exchanges) 6 at the sites A and H send a unicast message (such as lamp information) from the IP exchange (TM) 2 via the line (network operation system) 5. Multicast message conversion processing is performed on the unicast message, and the converted multicast message (solid line display) is provided to all IP terminals Eqi in the base (base A and base N).

  FIG. 15 is a base multicast operation backup explanatory diagram of one embodiment of the IP converter according to the present invention. In FIG. 15, in the site A, the multicast conversion device 6 is connected to the operational system (A system) of the line (network) 5 and receives a common message from the IP exchange (TM) 2 as a unicast message (shown by a broken line). And provided to all IP terminals Eqi in the site A by multicast messages (indicated by solid lines).

  On the other hand, the IP-CONV (IP converter) 8 is connected to the operational system (B system) of the circuit (network) 5 and is in the operational state, but from the IP switch (TM) 2 via the operational system (B system) circuit. Since the unicast message is not transmitted, the operation is stopped.

  From this state, when a failure occurs in the multicast conversion device 6 and unicast-multicast conversion cannot be performed, the IP exchange (TM) 2 cannot confirm communication from the multicast conversion device 6. A failure is detected, the standby system (B system) of the line (network) 5 is set as the active system, and a unicast message (displayed with a broken line) is transmitted to the IP-CONV (IP converter) 8 via the standby system (B system). .

  When the IP-CONV (IP converter) 8 receives a unicast message (dashed line display) via the standby system (B system) of the line (network) 5, it performs a multicast message conversion process on the unicast message (dashed line display). The converted multicast message (shown by a solid line) is provided to all IP terminals Eqi in the site A.

  Due to the duplex configuration of the operation system (system A) and standby system (system B) of the line (network) 5, and the unicast-multicast conversion device of the multicast conversion device 6 and the IP-CONV (IP converter) 8. Multicast message operation within the base can be ensured. In addition, although the base A was demonstrated in FIG. 15, it is the same also about all the bases of the base A1-base Hn shown in FIG.

  Next, the switching operation from the multicast conversion device to the IP-CONV (IP converter) and the switching operation from the IP-CONV (IP converter) to the multicast conversion device 6 in common message communication will be described. The IP exchange 2, the multicast conversion device 6, and the IP-CONV (IP converter) 8 are represented by TM, B-TM, and IP-CONV.

  FIG. 16 is an operation flowchart of one embodiment of common message communication according to the present invention. In FIG. 16, the TM sends “communication monitoring” to the B-TM, but cannot detect “communication monitoring (STB)” from the B-TM and detects “B-TM communication monitoring NG”. . The B-TM shifts from STB (standby state) to ACT (operating state) when communication NG is detected, and stops the multicast conversion operation.

  Therefore, TM switches from B-TM to IP-CONV and sends a unicast message. In addition, switching back from the IP-CONV to the B-TM is performed by a manual command, linked to the manual switching back command, and unicast message transmission from the TM is also switched back to the B-TM.

  TM transmits “unicast message (1)” to IP-CONV and confirms “ACK” from IP-CONV.

  Subsequently, the TM transmits “unicast message (2)” to the IP-CONV and confirms “ACK” from the IP-CONV. However, in the case of ACK retransmission NG also from IP-CONV, TM only performs log collection.

  Subsequently, the TM sends “communication monitoring” to the B-TM and detects “communication monitoring (ACT)” from the B-TM. The STB state is entered, and the state of B-TM is recognized.

  B-TM does not perform multicast conversion when it receives a unicast message in the ACT state.

  When TM is a manual switching command and B-TM makes a “switching request”, B-TM receives a “response”, and B-TM recovers from the ACT state to the STB state. "Monitor (STB)" is sent out.

  When the TM detects “communication monitoring (STB)” from the B-TM, the TM transmits a “unicast message (3)” to the B-TM and receives “ACT” from the B-TM. At this point, IP-CONV stops the multicast conversion operation.

  FIG. 17 is an operation flowchart of another embodiment of common message communication according to the present invention. In FIG. 17, when there is no communication monitoring from TM to B-TM, B-TM detects “communication monitoring NG”, shifts from STB (standby state) to ACT (operation state), and performs multicast conversion operation. Stop.

  If the TM cannot detect the communication NG of the B-TM and transmits a unicast message to the B-TM, the TM switches to the IP-CONV and transmits the unicast message by ACK retransmission NG.

  TM transmits “unicast message (1)” to B-TM even if communication monitoring from B-TM becomes NG, but “ACK” from B-TM cannot be confirmed. "Unicast message (1)" can be transmitted to IP-CONV, and "ACK" from IP-CONV can be confirmed, B-TM is switched to IP-CONV, and IP-CONV to the IP terminal in the base A multicast message will be provided to Eqi.

  Subsequently, the TM transmits “multicast message (2)” to the B-TM or the B-TM has not recovered from the failure and the “ACK” from the B-TM cannot be confirmed. "Cast message (2)" is transmitted to IP-CONV, and "ACK" from IP-CONV is confirmed.

  Even at this time, the TM cannot confirm the “communication monitoring (STB)” from the B-TM, and detects the B-TM communication monitoring NG.

  Thereafter, the operation of the TM communication monitoring NG is the same as the operation flow shown in FIG.

  In the IP telephone system according to the present invention, the main controller of the IP exchange is duplicated, the signal control device is made redundant by N + 1, the line is duplicated, and the backup exchange is provided at each site, so that the failure of the apparatus or the line The system can be backed up against any failure, and can be applied to any IP telephone system.

Block diagram of an embodiment of an IP telephone system according to the present invention Embodiment connection diagram of main controller and signal controller according to the present invention An explanatory view of one embodiment of switching of a signal control device according to the present invention Communication control operation sequence diagram of an embodiment of a signal control device according to the present invention Communication control operation sequence diagram of another embodiment of the signal control device according to the present invention Switching operation sequence diagram of an embodiment of a signal control device according to the present invention Port switching explanatory drawing of one embodiment of the signal control device according to the present invention LAN port switching sequence diagram of an embodiment of the present invention Switching sequence diagram of another embodiment of LAN port according to the present invention Overview of operation of one embodiment of backup switch according to the present invention One embodiment of the backup exchange according to the present invention Operation sequence diagram from standby system to active system One embodiment of the backup exchange according to the present invention Operation sequence diagram from the active system to the standby system Relay system diagram of one embodiment of common message communication according to the present invention Embodiment of Multicast Conversion Device 6 (Backup Switch) According to the Invention Unicast-multicast conversion explanatory diagram An embodiment of the IP converter according to the present invention. Operation flow diagram of one embodiment of common message communication according to this invention Operation flow diagram of another embodiment of common message communication according to the present invention

Explanation of symbols

1 IP telephone system 2 IP exchange (TM)
3 Main controller (CC)
3a Main controller (ACT system)
3b Main controller (SBY system)
4 Signal control devices (SC-0 to SC-7)
5 lines (network)
5a A system network 5b B system network 6 Backup switchboard (B-TM)
7a, 7b Gateway (GW)
8 IP-CONV (IP converter)
SC-N Backup signal controller (backup SC)
BU, BU-a, BU-b Control bus PHY0 A system port PHY1 B system port Eqi IP terminal

Claims (4)

A main control device that controls the overall operation of the IP exchange, the center of the center including a plurality of signal control devices that accommodates a plurality of IP terminals for each base through a line and performs call control through the control of the main control device An IP switch, the line connecting the IP switch and the base, a backup switch that detects a failure of the IP switch and a fault of the line, and backs up the base, and the plurality of IP terminals In an IP telephone system comprising a plurality of said bases and centrally managing / operating all IP terminals with an IP exchange,
One of the plurality of signal control devices is a spare signal control device that does not accommodate the IP terminal,
The main control device sets different IP addresses to the plurality of signal control devices, and when a failure occurs in one signal control device, the signal control in which the failure occurs is set as the IP address of the spare signal control device. Change to the IP address of the device, perform the control to switch the signal control device in which the failure has occurred to a spare signal control device,
IP telephone system the switched spare signal control device, which takes over the IP address of the IP terminal which has been accommodated in the failed signal the controller continues the call a call control and executes up to Tama.   2. The IP telephone according to claim 1, wherein the main control device performs communication confirmation with the plurality of signal control devices, and determines that a failure has occurred when communication with the corresponding signal control device cannot be confirmed. system.   2. The IP telephone system according to claim 1, wherein when switching to a spare signal control device, the main control device checks a minimum initial condition and shortens the switching time.   The main control device has a duplex configuration of an active system and a standby system. The standby system captures and stores call control information of the active system, and when the active system fails, the standby system is 2. The IP telephone system according to claim 1, wherein the IP telephone system operates as an active system.

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