JP2015056759A - Communication control device, control device, and communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to continue service for transmitting/receiving communication data between local terminals, even when abnormality is detected at a control unit of a communication control device for performing communication control of the local terminal.SOLUTION: A communication control device according to an embodiment comprises a control unit, a communication unit, and a path control unit. The control unit generates a communication control instruction for instructing communication control between a first terminal and a second terminal connected to the first terminal through a network, on the basis of control data received from the first terminal; and transmits the communication control instruction to an external communication control device for performing communication control of the second terminal. The communication unit can transmit communication data received from the first terminal to the external communication control device, when communication between the first and second terminals is enabled. When abnormality of the control unit is detected, the path control unit makes the communication unit transfer the control data and communication data to a predetermined fault countermeasure device capable of transmitting the communication control instruction and communication date to the external communication control device.

Description

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

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

  On the other hand, in the case of a communication system in which devices are distributed on an IP network, it is assumed that communication services cannot be continued when a failure occurs in a terminal device that performs call connection of a client terminal. In general, a server or a control device that aggregates the functions of devices included in a communication system is greatly affected by a stop of a communication service, and therefore, countermeasures such as duplication are often taken. However, terminal devices often rely on the host device side on the IP network to simplify processing and reduce costs, and it is difficult to take countermeasures such as duplication. Therefore, communication services can be continued by a redundant device (redundant system) for a failure that has occurred in a server or a control device, but communication services must be stopped for a failure that has occurred in a terminal device.

  Therefore, a technique is disclosed in which communication services are continued by automatically switching a terminal device to communication with a network using a wireless device when a failure occurs in communication with a network using a wired device. .

JP 2010-291306 A

  However, in the prior art, when the terminal device is a device that performs call connection of a client terminal, if an abnormality that cannot process a call connection request from the client terminal occurs in a CPU (Central Processing Unit) included in the device, the client terminal Cannot be connected to the network and the communication service must be stopped.

  The communication control apparatus according to the embodiment includes a control unit, a communication unit, and a path control unit. The control unit generates a communication control instruction that instructs communication control between the first terminal and the second terminal connected to the first terminal via the network based on the control data received from the first terminal, It transmits to the external communication control apparatus which performs communication control of the 2nd terminal. The communication unit can transmit the communication data received from the first terminal to the external communication control device when communication between the first terminal and the second terminal becomes possible. When detecting an abnormality of the control unit, the path control unit causes the communication unit to transfer the control data and the communication data to a predetermined failure device that can transmit the communication control instruction and the communication data to the external communication control device.

FIG. 1 is a block diagram illustrating a configuration of a communication system according to the first embodiment. FIG. 2 is a block diagram illustrating a configuration of each unit included in the communication system according to the first embodiment. FIG. 3 is a diagram for explaining normal communication processing in the network device PS of the communication system according to the first embodiment. FIG. 4 is a diagram for explaining communication processing when an abnormality is detected in the CPU processing unit included in the network device of the communication system according to the first embodiment. FIG. 5 is a diagram for explaining communication processing in the network device of the communication system according to the first embodiment. FIG. 6 is a diagram for explaining an operation of continuing a service for transmitting and receiving communication data between local terminals when an abnormality is detected in the CPU processing unit of the network device in the communication system according to the first embodiment. . FIG. 7 is a diagram for explaining processing for setting a faulty network device for a network device by the control device of the communication system according to the first embodiment. FIG. 8 is a diagram illustrating a measurement result of the delay time by the network device of the communication system according to the first embodiment. FIG. 9 is a sequence diagram illustrating a flow of communication processing between local terminals in the communication system according to the first embodiment. FIG. 10 is a sequence diagram illustrating a flow of setting processing of the network device for failure by the control device of the communication system according to the first embodiment. FIG. 11 is a block diagram illustrating a configuration of a communication system according to the second embodiment. FIG. 12 is a block diagram illustrating a configuration of each unit included in the communication system according to the second embodiment.

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

(First embodiment)
FIG. 1 is a block diagram illustrating a configuration of a communication system according to the first embodiment. As shown in FIG. 1, the communication system 1 according to the present embodiment includes a local terminal LT1, LT2 (hereinafter referred to as a local terminal LT when it is not necessary to distinguish between the local terminals LT1, LT2), a network The devices PS1 and PS2 (hereinafter referred to as network devices PS when it is not necessary to distinguish between the network devices PS1 and PS2) and the failure network devices FPS1 and FPS2 (hereinafter referred to as failure network devices FPS1 and FPS2) If it is not necessary to do this, it is described as a fault network device FPS) and a control device S.

  The network device PS is connected to a network NW such as an IP network or a public communication network. The network device PS is an example of a communication control device that performs call connection (communication control) of the local terminal LT connected via a local line. The fault network device FPS is an example of a fault device that performs call connection of the local terminal LT instead of the network device PS when a fault (abnormality) occurs in the network device PS. The control device S is an example of an external control device that sets a failure network device FPS (predetermined failure device) that performs call connection of the local terminal LT instead of the network device PS as the network device PS. Further, the control device S instructs the network device PS to measure the delay time of communication between the network device PS and the faulty network device FPS.

  FIG. 2 is a block diagram illustrating a configuration of each unit included in the communication system according to the first embodiment. As shown in FIG. 2, the network device PS1 includes a local line unit 101 that transmits / receives various data to / from a local terminal LT1 connected via a local line, and a communication target among data received from the local terminal LT1. CPU (Central Processing Unit) processing unit 102 (an example of a control unit) that processes control data used for call connection of local terminal LT2, communication data to be transmitted to local terminal LT2 among data received from local terminal LT1, and local A communication processing unit 103 (an example of a communication unit) that processes communication data received from the terminal LT2, a data branching unit 104 that distributes data received from the local terminal LT1 to the CPU processing unit 102 or the communication processing unit 103, and a CPU processing unit 102, an abnormality in the CPU processing unit 102 is detected. A path control unit that controls the data branching unit 104 to distribute control data and communication data to the communication processing unit 103 and to transfer the control data and communication data to the network device for failure FPS by the communication processing unit 103 when the data branch is detected 105, and a delay time measuring unit 106 that measures a delay time of communication between the network device for failure FPS and the network device PS1. The network device PS2 is connected to the local terminal LT2 via a local line and has a configuration similar to that of the network device PS1.

  In the present embodiment, the communication processing unit 103, the data branching unit 104, and the path control unit 105 are the CPU processing unit 102 when the CPU processing unit 102 is abnormal, such as an FPGA (Field Programmable Gate Array) or a DSP (Digital Signal Processing). It is comprised by the apparatus which can operate | move independently.

  As shown in FIG. 2, the failure network device FPS includes a CPU processing unit 107 that processes control data received from the network device PS, a communication processing unit 108 that processes communication data received from the network device PS, and a network device. A data branching unit 109 for distributing control data and communication data received from the PS to the CPU processing unit 107 or the communication processing unit 108, and a path for controlling data distribution to the CPU processing unit 107 or the communication processing unit 108 by the data branching unit 109 And a control unit 110.

  As shown in FIG. 2, the control device S transmits a delay measurement instruction for instructing measurement of a delay time of communication between the network device PS and the network device for failure FPS to the network device PS, and measures the delay time. Based on the result, when an abnormality of the network device PS (CPU processing unit 102) is detected, a network device for failure FPS (a predetermined failure device) that performs call connection of the local terminal LT instead of the network device PS. Measurement range for selecting a failure network device FPS for measuring a delay time of communication with the network device PS among a plurality of failure network devices FPS (failure device candidates). And a determination unit 112.

  Next, a normal communication process in the network device PS of the communication system 1 according to the present embodiment will be described with reference to FIG. FIG. 3 is a diagram for explaining normal communication processing in the network device PS of the communication system according to the first embodiment.

  When the local line unit 101 receives data from the local terminal LT1 at normal time when no abnormality is detected in the CPU processing unit 102 of the network device PS1, the data branching unit 104 analyzes the received data and receives the received data. If the received data is communication data, the control data is sent to the communication processing unit 103.

  The CPU processing unit 102, based on the control data received from the data branching unit 103, the local terminal LT1 (an example of the first terminal) and the local terminal LT2 (second terminal) connected to the local terminal LT1 via the network NW. A call connection message (an example of a communication control instruction) is generated to instruct a call connection (an example of communication control) between (an example of terminals). Then, the CPU processing unit 102 transmits the generated call connection message to the network device PS2 (an example of an external communication control device) via the switch SW in accordance with a communication protocol such as SIP (Session Initiation Protocol). The CPU processing unit 102 receives a call connection message from the local terminal LT2 connected via the network NW, generates control data based on the received call connection message, and transmits the control data to the local terminal LT1.

  The communication processing unit 103, for example, data such as RTP (Real-time Transport Protocol) when communication between the local terminal LT1 and the local terminal LT2 becomes possible due to the transmission of the call connection message by the CPU processing unit 102. According to the transmission protocol, the communication data received from the data branching unit 104 is transmitted to the network device PS2 via the switch SW. Furthermore, when the communication processing unit 103 becomes ready for communication between the local terminal LT1 and the local terminal LT2 due to the transmission of the call connection message by the CPU processing unit 102, the communication processing unit 103 passes the network NW according to the data transmission protocol. Communication data received from the local terminal LT2 is transmitted to the local terminal LT1. Through the above processing, the network device PS1 establishes call connection between the local terminals LT and establishes communication between the local terminals LT.

  Next, communication processing when an abnormality is detected in the CPU processing unit 102 included in the network device PS of the communication system 1 according to the present embodiment will be described with reference to FIG. FIG. 4 is a diagram for explaining communication processing when an abnormality is detected in the CPU processing unit included in the network device of the communication system according to the first embodiment.

  The route control unit 105 is configured such that, for example, the control data is sent from the data branching unit 104 to the CPU processing unit 102, but the call connection message is not generated and the call connection of the local terminal LT is not realized. Detect abnormalities. When the path control unit 105 detects a failure in the CPU processing unit 102, the path control unit 105 controls the data branching unit 104 to send control data and communication data received by the local line unit 101 to the communication processing unit 103. The control data and communication data are transferred by the communication processing unit 103 to the network device FPS for failure that can transmit the call connection message and the communication data to the network device PS. Thereby, the network device PS1 automatically shifts to a transfer mode in which the control data and communication data received from the local terminal LT1 are transferred to the network device for failure FPS1.

  Specifically, when the path control unit 105 detects an abnormality in the CPU processing unit 102, the path control unit 105 transmits, to the communication processing unit 103, paths (for the number of channels that can transmit control data and communication data to the fault network FPS). (Hereinafter referred to as a failure path). Then, the communication processing unit 103 establishes the failure path and transmits the control data and the communication data to the failure network device FPS by using the established failure path. Transfer to the fault network device FPS is realized.

  Further, the path control unit 105 causes the control data and the communication data to be transferred to the failure network device FPS1 which is the failure device candidate set by the control device S (an example of the external control device). At that time, the path control unit 105 transfers the control data and the communication data to the network device for failure FPS1 connected to the network device PS1 via the network NW. This eliminates the need to provide a failure network device FPS for each network device PS (in other words, one failure network device is made to function as a failure device that performs call connection instead of a plurality of network devices PS. Therefore, an increase in cost due to the provision of the fault network device FPS in the communication system 1 and an increase in the space in which the fault network device FPS is provided can be minimized.

  In the present embodiment, the path control unit 105 stores identification information such as an IP address that can identify the network device for failure FPS set by the control device S as internal information. Then, the path control unit 105 transfers control data and communication data to the failure network device FPS specified by the identification information stored as the internal information.

  In the present embodiment, the path control unit 105 transfers control data and communication data to the network device for failure FPS set by the control device S. However, the present invention is not limited to this. Control data and communication data may be transferred to the fault network device FPS set by the administrator through the user interface of the network device PS. This eliminates the need to provide the control device S having a function of setting the network device for failure FPS for the network device PS, thereby reducing the cost of the communication system 1.

  Next, communication processing in the fault network device FPS of the communication system 1 according to the present embodiment will be described with reference to FIG. FIG. 5 is a diagram for explaining communication processing in the network device of the communication system according to the first embodiment.

  The route control unit 110 detects whether or not the communication processing unit 108 has received control data and communication data via a failure path established by the network device PS. When the path control unit 110 detects that a fault path has been established by the network device PS and control data and communication data have been received via the fault path, the path control unit 110 controls the data branch unit 109 to perform communication. The control data received by the processing unit 108 is sent to the CPU processing unit 107, and the communication data received by the communication processing unit 108 is sent to the communication processing unit 108.

  Specifically, when receiving data through the failure path established by the network device PS, the communication processing unit 108 sends the received data to the data branching unit 109. The data branching unit 109 analyzes the received data. If the received data is control data, the data branching unit 109 sends the control data to the CPU processing unit 107. If the received data is communication data, the data branching unit 109 The communication data is sent to the communication processing unit 108.

  Similar to the CPU processing unit 102 of the network device PS1, the CPU processing unit 107 generates a call connection message instructing call connection between the local terminal LT1 and the local terminal LT2 based on the control data received from the data branching unit 109. For example, a call connection message is transmitted to the network device PS2 via the switch SW in accordance with a communication protocol such as SIP.

  Further, the communication processing unit 108 is in a state in which communication between the local terminal LT1 and the local terminal LT2 is possible by the transmission of the call connection message by the CPU processing unit 107 in the same manner as the communication processing unit 103 of the network device PS1. In this case, for example, the communication data received from the data branch unit 109 is transmitted to the network device PS2 via the switch SW according to a data transmission protocol such as RTP. As described above, the fault network device FPS replaces the call connection function by the network device PS1 in which the abnormality is detected in the CPU processing unit 102, and establishes communication between the local terminal LT1 and the local terminal LT2, thereby Even when a failure occurs in the network device PS1 as a device, it is possible to continue a service for transmitting and receiving communication data between the local terminals LT.

  Next, referring to FIG. 6, in the communication system 1 according to the present embodiment, when an abnormality is detected in the CPU processing unit 102 of the network device PS, an operation for continuing a service for transmitting / receiving communication data between the local terminals LT Will be described. FIG. 6 is a diagram for explaining an operation of continuing a service for transmitting and receiving communication data between local terminals when an abnormality is detected in the CPU processing unit of the network device in the communication system according to the first embodiment. .

  In a normal time when no abnormality is detected in the CPU processing unit 102 of the network device PS1, the CPU processing unit 102 generates a call connection message based on the control data received from the local terminal LT1, and the generated call connection message Is transmitted to the network device PS2 connected to the local terminal LT2 via a local line to enable communication between the local terminal LT1 and the local terminal LT2. The communication processing unit 103 establishes communication between the local terminal LT1 and the local terminal LT2 by transmitting and receiving communication data between the local terminal LT1 and the local terminal LT2 using the normal time communication path P1.

  On the other hand, when an abnormality of the CPU processing unit 102 is detected by the route control unit 105 of the network device PS1, the CPU processing unit 102 cannot generate a call connection message, transmit the call connection message, or the like. Therefore, the path control unit 105 controls the data branching unit 104 to send the control data and communication data received from the local terminal LT1 to the communication processing unit 103 and instruct the establishment of the failure path P2. The communication processing unit 103 establishes the failure path P2, and uses the failure path P2 to transfer control data and communication data to the failure network device FPS1 set in advance by the control device S, The device PS1 is shifted to the transfer mode.

  The CPU processing unit 107 of the failure network device FPS1 generates a call connection message based on the control data transferred from the network device PS1. Then, the CPU processing unit 107 transmits the generated call connection message to the network device PS2 to enable communication between the local terminal LT1 and the local terminal LT2 via the failure network device FPS1. The communication processing unit 108 establishes communication between the local terminal LT1 and the local terminal LT2 by transmitting / receiving communication data to / from the local terminal LT2 using the failure communication path P3. Thereby, even when an abnormality is detected in the CPU processing unit 102 of the network device PS1 as a terminal device, the service for transmitting and receiving communication data between the local terminal LT1 and the local terminal LT2 is continued.

  Next, processing for setting the fault network device FPS for the network device PS will be described with reference to FIGS. 2 and 7. FIG. 7 is a diagram for explaining processing for setting a faulty network device for a network device by the control device of the communication system according to the first embodiment.

  The measurement range determination unit 112 (an example of a selection unit) of the control device S measures a delay time of communication with the network device PS among a plurality of failure network devices FPS (a plurality of failure device candidates) included in the communication system 1. A failure network device FPS (for example, failure network devices FPS1, FPS2, and FPS3) that is a failure device candidate to be selected is selected. Then, the delay measurement instruction unit 111 (an example of a transmission unit) of the control device S sends a delay measurement instruction for instructing measurement of a delay time of communication between the selected network device for failure FPS and the network device PS1 every predetermined time. To the network device PS1.

  Each time the delay measurement unit 106 of the network device PS1 receives a delay measurement instruction from the control device S, the delay measurement unit 106 measures the delay time of communication between the network device PS1 and each of the network devices for failure FPS1, FPS2, and FPS3. Then, the delay measurement unit 106 transmits the delay time measurement result to the control device S.

  Based on the delay time measurement result received from the network device PS1, the measurement range determination unit 112 of the control device S determines a faulty network device FPS that performs call connection instead of the network device PS1. Then, the measurement range determination unit 112 notifies the network device PS1 of identification information for identifying the determined failure network device FPS, and sets the failure network device FPS in the network device PS.

  Here, referring to FIG. 8, the network device PS1 is selected based on the process of selecting the network device for failure FPS for measuring the delay time of communication with the network device PS1 and the measurement result of the delay time by the network device PS1. Processing for setting the fault network device FPS will be described. FIG. 8 is a diagram illustrating a measurement result of the delay time by the network device of the communication system according to the first embodiment.

  As illustrated in FIG. 8, the measurement range determination unit 112 measures the delay time of communication with the network device PS in association with the network device ID identified by the network device PS included in the communication system 1. A fault network device ID for identifying a fault, a measurement history of a delay time of communication between the network device PS and the fault network device FPS, and a faulty connection destination representing the fault network device FPS set in the network device PS I remember it.

  Then, the measurement range determining unit 112 sets the network device PS for failure with the shortest delay time measured by the delay measuring unit 106 of the network device PS to the network device PS, and sets the network device for failure FPS at the time of failure. It is stored in association with the network device ID as a connection destination.

  In addition, the measurement range determination unit 112 is configured to communicate with the communication system based on the delay time measurement history stored in association with the network device ID (for example, PS1) of the network device PS to be set for setting the failure network device FPS. The failure network device FPS for measuring the delay time of communication with the network device PS1 is selected from the failure network devices FPS of 1. Specifically, the measurement range determination unit 112 determines the previously measured delay time among the failure network devices FPS specified by the failure network device ID stored in association with the network device ID of the network device PS1. A predetermined number (for example, three) of failure network devices FPS (for example, failure network devices FPS with failure network device IDs 101, 103, and 105) are selected in order from the short failure network device FPS.

  Further, the measurement range determination unit 112 has the same network device PS (for example, the fault network device FPS with the shortest measured delay time among the network devices PS other than the setting target network device PS1 included in the communication system 1 (for example, , The failure network device FPS (for example, the failure network device FPS with the failure network device IDs 109, 101, and 107) measured for the delay time of the communication with the network device PS3) is the communication delay with the network device PS1. Select as network device FPS for failure to measure time.

  Then, the delay measurement instruction unit 111 uses the network device for failure FPS selected by the measurement range determination unit 112 by the above-described processing (for example, the network device for failure of the failure network device ID: 101, 103, 105, 107, 109). A delay measurement instruction for instructing measurement of a delay time of communication with the FPS) is transmitted to the network device PS1.

  In the present embodiment, the measurement range determination unit 112 selects a failure network device FPS that measures the delay time of communication with the network device PS to be set based on the delay time measurement history in the two network devices PS. However, the present invention is not limited to this, and the network device FPS for failure for measuring the delay time of communication with the network device PS to be set is selected based on the measurement history of the delay time of three or more network devices PS. You may do it.

  In the present embodiment, the measurement range determination unit 112 selects a failure network device FPS for measuring the delay time of communication with the network device PS to be set based on the delay time measurement history in the network device PS. However, the present invention is not limited to this. For example, the failure network device FPS for measuring the delay time of communication with the network device PS to be set is selected based on the load of each of the plurality of failure network devices FPS. You may do it. Specifically, the measurement range determining unit 112 sets a predetermined number of failure network devices FPS in order from the failure network device FPS with the smallest load among the plurality of failure network devices FPS to the network device PS to be set. The network device is selected as a failure network device FPS for measuring the communication delay time.

  Next, the flow of communication processing between the local terminals LT of the communication system 1 according to the present embodiment will be described with reference to FIG. FIG. 9 is a sequence diagram illustrating a flow of communication processing between local terminals in the communication system according to the first embodiment.

  When the local line unit 101 receives control data instructing call connection from the local terminal LT1 at normal time when no abnormality is detected in the CPU processing unit 102 of the network device PS1 (step S901), the data branching unit 104 receives the data. The control data is distributed to the CPU processing unit 102. Based on the received control data, the CPU processing unit 102 generates a call connection message instructing call connection of the local terminal LT2 that is a communication partner of the local terminal LT1. Then, the CPU processing unit 102 transmits the generated call connection message to the network device PS2 connected to the local terminal LT2 via the local line (step S902).

  When the CPU processing unit 102 of the network device PS2 receives the call connection message transmitted from the network device PS1, the CPU processing unit 102 generates control data based on the received call connection message, and transmits the control data via the data branching unit 104. The generated control data is transmitted to the local terminal LT2 via the local line unit 101 (step S903). Thereafter, when the local line unit 101 receives control data instructing a response to the call connection from the local terminal LT2 (step S904), the data branching unit 104 distributes the received control data to the CPU processing unit 102. Based on the received control data, the CPU processing unit 102 generates a call connection message that notifies a response to the call connection from the local terminal LT2. Then, the CPU processing unit 102 transmits the generated call connection message to the network device PS1 connected to the local terminal LT1 via a local line (step S905).

  When the CPU processing unit 102 of the network device PS1 receives the call connection message transmitted from the network device PS2, the CPU processing unit 102 generates control data based on the received call connection message, and via the data branching unit 104, The generated control data is transmitted to the local terminal LT1 via the local line unit 101 (step S906). The communication processing unit 103 transmits the communication data received from the local terminal LT1 according to the data transmission protocol while the communication between the local terminal LT1 and the local terminal LT2 is possible by the transmission of the call connection message by the CPU processing unit 102. To the local terminal LT2 via the network device PS2. Furthermore, the communication processing unit 103 transmits the communication data received from the local terminal LT2 via the network device PS to the local terminal LT1 via the data branching unit 104 and the local line unit 101. As a result, the network device PS1 establishes communication between the local terminal LT1 and the local terminal LT2 (step S907).

  Thereafter, when detecting a failure (abnormality) in the CPU processing unit 102 (step S908), the route control unit 105 of the network device PS1 instructs the communication processing unit 103 to establish a failure path. Then, the communication processing unit 103 establishes a failure path (step S909), and uses the established failure path to transfer control data to a failure network device FPS set in advance, for example, the failure network device FPS1. Transfer (step S910).

  When detecting that the communication processing unit 108 has received the control data, the path control unit 110 of the network device for failure FPS1 controls the data branching unit 109 to receive the control data received by the communication processing unit 108 as a CPU processing unit. 107 to send. Based on the control data, the CPU processing unit 107 generates a call connection message instructing call connection of the local terminal LT2 that is a communication partner of the local terminal LT1. Then, the CPU processing unit 107 transmits the generated call connection message to the network device PS2 connected to the local terminal LT2 via the local line (step S911).

  When the CPU processing unit 102 of the network device PS2 receives the call connection message transmitted from the network device for failure FPS1, it generates control data based on the received call connection message, and also via the data branching unit 104. The generated control data is transmitted to the local terminal LT2 via the local line unit 101 (step S912). Thereafter, when the local line unit 101 receives control data instructing a response to the call connection from the local terminal LT2 (step S913), the data branching unit 104 distributes the received control data to the CPU processing unit 102. Based on the received control data, the CPU processing unit 102 generates a call connection message that notifies a response to the call connection from the local terminal LT2. Then, the CPU processing unit 102 transmits the generated call connection message to the failure network device FPS1 (step S914).

  When the CPU processing unit 107 of the network device for failure FPS1 receives the call connection message transmitted from the network device PS2, it generates control data based on the received call connection message and communicates the generated control data. The data is transmitted to the network device PS1 via the processing unit 108 (step S915).

  When the communication processing unit 103 of the network device PS1 receives the control data transmitted from the failure network device FPS1, the data branching unit 109 transmits the received control data to the local terminal LT1 via the local line unit 101. . The communication processing unit 103 transmits the communication data received from the local terminal LT1 to the data transmission protocol while the communication between the local terminal LT1 and the local terminal LT2 is possible by transferring the control data to the network device for failure FPS1. To the local terminal LT2 via the failure network device FPS1. Further, the communication processing unit 103 transmits the communication data received from the local terminal LT2 via the failure network device FPS1 to the local terminal LT1 via the data branching unit 104 and the local line unit 101. As a result, the network device PS1 continues communication between the local terminal LT1 and the local terminal LT2 (step S916).

  Next, the flow of the setting process of the network device FPS for failure by the control device S of the communication system 1 according to the present embodiment will be described using FIG. FIG. 10 is a sequence diagram illustrating a flow of setting processing of the network device for failure by the control device of the communication system according to the first embodiment.

  The measurement range determination unit 112 of the control apparatus S measures a fault network device FPS (for example, a fault delay device FPS (for example, the network device PS1) for measuring a delay time of communication with the network device PS to be set (for example, the network device PS1). The fault network devices FPS1, FPS2, and FPS3) are selected. Then, the delay measurement instruction unit 111 transmits to the network device PS1 a delay measurement instruction that instructs measurement of the delay time of communication with each of the selected failure network devices FPS1, FPS2, and FPS3 (step S1001).

  When the delay measurement unit 106 of the network device PS1 receives the delay measurement instruction from the control device S, the delay measurement unit 106 measures the delay time of communication between the network device PS1 and each of the network devices for failure FPS1, FPS2, and FPS3 (step S1002). Then, the delay measurement unit 106 notifies the control device S of the delay time measurement result (step S1003).

  The measurement range determination unit 112 of the control device S, based on the delay time measurement result received from the network device PS1, substitutes for the network device PS1 for the failure network device FPS (for example, failure Network device FPS1). Then, the measurement range determination unit 112 notifies the network device PS1 of identification information (failure connection destination) for identifying the determined failure network device FPS1 (step S1004), and the failure network device FPS1 is notified to the network device PS1. (Step S1005).

  As described above, according to the communication system 1 of the first embodiment, since the network device for failure FPS can replace the call connection of the local terminal LT instead of the network device PS, the network device as a terminal device Even when an abnormality is detected in the CPU processing unit 102 of PS1, it is possible to continue the service of transmitting / receiving communication data between the local terminal LT1 and the local terminal LT2.

  In the present embodiment, the measurement range determination unit 112 of the control device S sets the failure network device FPS as a predetermined failure device that replaces the call connection of the local terminal LT by the network device PS. However, the present invention is not limited to this. For example, the network device PS (another communication control device) may be set as a predetermined failure device. In this case, the network device PS set as a predetermined failure device is transferred from another network device PS in addition to the call connection of the local terminal LT connected to the network device PS via a local line. The call connection message and communication data are transmitted based on the control data and communication data.

  Further, in this embodiment, when an abnormality is detected in the CPU processing unit 107 of the fault network device FPS, even if control data is transferred from the network device PS, a call connection message is transmitted based on the transfer data. Although it cannot be performed, when the path control unit 110 of the fault network device FPS detects an abnormality in the CPU processing unit 107, the communication processing unit 108 transfers the control data and communication data transferred from the network device PS to other faults. Even if an abnormality is detected in the CPU processing unit 107 of the failure network device FPS by transferring the call connection message and communication data to the other failure network device FPS by transferring to the failure network device FPS Between LT It is possible to continue the service for transmitting and receiving Oite communication data.

(Second Embodiment)
In this embodiment, when a failure occurs in the CPU processing unit of the network device, the external control device that controls the entire communication system functions as a failure control device, and the call connection of the local terminal is performed instead of the network device. It is an example to do. In the following description, description of the same parts as those in the first embodiment is omitted.

  FIG. 11 is a block diagram illustrating a configuration of a communication system according to the second embodiment. As shown in FIG. 11, the communication system 11 according to the present embodiment does not need to distinguish between the local terminal LT, the network device PS, and the failure control devices FS1 and FS2 (hereinafter, failure control devices FS1 and FS2). In this case, it is described as a failure control device FS) and a control device S1.

  The failure control device FS (an example of an external control device) functions as an external control device that controls the entire communication system 11 when no abnormality has occurred in the CPU processing unit 102 of the network device PS, and the network device PS When an abnormality is detected, it can function as a failure control device that performs call connection of the local terminal LT instead of the network device PS. The control device S1 controls the entire communication system 11 such as instructing the network device PS to measure the delay time of communication between the network device PS and the network device FPS for failure, and performs predetermined control on the network device PS. The failure control devices FS1 and FS are set as the failure devices.

  FIG. 12 is a block diagram illustrating a configuration of each unit included in the communication system according to the second embodiment. As shown in FIG. 12, the failure control apparatus FS, in addition to the generation and transmission of a call connection message based on the control data received from the network device PS, for example, a delay measurement instruction unit 121 or measurement included in the control apparatus S1 described later A CPU processing unit 130 capable of executing control of the entire communication system 11 such as processing in the range determining unit 122, a communication processing unit 108, a data branching unit 109, and a path control unit 110 are included.

  As shown in FIG. 12, the control device S1 transmits to the network device PS a delay measurement instruction for instructing measurement of the delay time of communication between the network device PS and the failure control device FS, and measures the delay time. Based on the result, a delay measurement instructing unit 121 that sets a fault control device FS (an example of a predetermined fault device) for the network device PS when an abnormality is detected in the network device PS (CPU processing unit 102). And a measurement range determination unit 122 that selects a failure control device FS that measures a delay time of communication with the network device PS from among a plurality of failure control devices FS (an example of a failure device candidate). ing.

  As described above, according to the communication system 11 of the second embodiment, when a failure is detected in the network device PS, the failure control is performed as a failure device that performs call connection of the local terminal LT instead of the network device PS. By setting the device FS, when a failure is detected in the network device PS, a dedicated failure device that performs call connection instead of the network device PS (for example, the failure network device FPS of the first embodiment) Therefore, the cost for realizing the communication system 11 by providing the failure device can be reduced.

  As described above, according to the first and second embodiments, even when an abnormality is detected in the CPU processing unit 102 of the network device PS as the terminal device, the service for transmitting and receiving communication data between the local terminals LT is continued. be able to.

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

DESCRIPTION OF SYMBOLS 1,11 Communication system 101 Local line part 102,107,130 CPU processing part 103,108 Communication processing part 104,109 Data branch part 105,110 Path control part 106 Delay measurement part 111,121 Delay measurement instruction part 112,122 Measurement Range determination unit LT local terminal PS network device FPS network device for failure S, S1 controller NW network FS controller for failure

Claims (13)

Based on the control data received from the first terminal, a communication control instruction for instructing communication control between the first terminal and the second terminal connected to the first terminal via the network is generated, and the second terminal A control unit that transmits to an external communication control device that performs communication control of the terminal;
A communication unit capable of transmitting communication data received from the first terminal to the external communication control device when communication between the first terminal and the second terminal is enabled;
When the abnormality of the control unit is detected, the control unit and the communication data are transferred by the communication unit to a predetermined failure device capable of transmitting the communication control instruction and the communication data to the external communication control device. A routing control unit,
A communication control device.   The communication control apparatus according to claim 1, wherein the path control unit causes the predetermined failure device connected to the communication unit via a network to transfer the control data and the communication data.   The communication control apparatus according to claim 2, wherein the path control unit causes the predetermined failure device that is a failure device candidate set by an external control device to transfer the control data and the communication data.   A measurement unit configured to measure a delay time of communication between the failure control device candidate selected by the external control device among the plurality of failure device candidates and the communication control device and transmit the measured delay time to the external control device; The communication control device according to claim 3.   The communication control device according to claim 4, wherein the measurement unit measures the delay time according to a measurement instruction transmitted from the external control device every predetermined time.   The communication control apparatus according to claim 1, wherein the predetermined failure device is another communication control apparatus connected to the external communication control apparatus via a network.   The communication control device according to claim 1, wherein the predetermined failure device is the external control device. Based on the control data received from the first terminal, a communication control instruction for instructing communication control between the first terminal and the second terminal connected to the first terminal via the network is generated, and the second terminal When the communication between the first terminal and the second terminal is enabled, the communication data received from the first terminal is transmitted to the external communication control device that performs communication control of the terminal. When a communication unit that can be transmitted to an external communication control device and an abnormality of the control unit is detected, the communication control instruction and the communication data can be transmitted to the external communication control device with respect to a predetermined failure device, A communication control device comprising: a path control unit that transfers the control data and the communication data by a communication unit; and a measurement unit that measures a delay time of communication between the own device and a plurality of failure device candidates. Predetermined A control device for setting the fault equipment,
Based on the measurement history of the delay time, a selection unit that selects the failure device candidate for measuring the delay time among the plurality of failure device candidates;
A transmission unit that transmits a measurement instruction that instructs measurement of the delay time of communication between the selected failure device candidate and the communication control device;
A control device comprising:   The control device according to claim 8, wherein the selection unit selects the failure device candidate set in another communication control device with the same failure device candidate having the shortest delay time measured last time.   9. The control device according to claim 8, wherein the selection unit selects the failure device candidate for measuring the delay time from the plurality of failure device candidates based on a load of each of the plurality of failure device candidates. .   The control device according to claim 10, wherein the selection unit selects the failure device candidate with a low load from the plurality of failure device candidates. Based on the control data received from the first terminal, a communication control instruction for instructing communication control between the first terminal and the second terminal connected to the first terminal via the network is generated, and the second terminal When the communication between the first terminal and the second terminal is enabled, the communication data received from the first terminal is transmitted to the external communication control device that performs communication control of the terminal. A communication system comprising a communication control unit capable of transmitting to an external communication control device, and a predetermined failure device capable of communicating with the communication control device,
When the communication control device detects an abnormality of the control unit, the communication control unit sends the control data to the predetermined failure device capable of transmitting the communication control instruction and the communication data to the external communication control device. And a path control unit for transferring the communication data,
A communication system comprising: The communication system includes a control device that sets the predetermined failure device for the communication control device;
The communication control device includes a measurement unit that measures a delay time of communication between the communication control device and a plurality of failure device candidates.
The control device selects a failure device candidate for measuring the delay time from the plurality of failure device candidates based on the delay time measurement history, and the selected failure device candidate. The communication system according to claim 12, further comprising: a transmission unit that transmits a measurement instruction that instructs measurement of the delay time of communication with the communication control device to the communication control device.

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