JP2012129864A - Communication system and method for controlling user access device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently determine an adequate control route as the control route of an active system among redundant remote control routes for a user access device.SOLUTION: A communication system of an embodiment of the invention comprises a user access device 3, and communication devices 5 and 6. Each of the communication devices has a control route with the user access device. The user access device determines that one of the control route confirmed as normal (0 system control route) between the two control routes is the control route of the active system and the other control route (1 system control route) is the control route of the standby system.

Description

  The present invention relates to a communication system and a method for controlling a user access device in the communication system, and more particularly to control path redundancy for controlling the user access device.

  In recent years, a packet switching network connection service using an Ethernet (registered trademark, hereinafter the same) line has been provided by a communication carrier. In particular, a dedicated line connection service using Ethernet technology is provided. In a dedicated line connection service using a packet switching network, a plurality of user lines can be logically multiplexed on one physical line. In such a communication network, a technique for ensuring and improving its reliability is important.

  For this reason, in addition to OAM (Operation Administration and Maintenance), which is a technology for failure management and performance monitoring, a path between two points is made redundant, and when a failure occurs, APS (Automatic) is automatically switched from the working path to the backup path. Protection Switching) is being implemented. As for Ethernet technology, standardization of OAM and APS technologies has been carried out. For example, Non-Patent Document 1, Non-Patent Document 2, and Non-Patent Document 3 define OAM and APS technologies in Ethernet.

  Communication path redundancy can also be performed by using two carrier communication networks. For example, Patent Document 1 discloses a system that uses two carrier communication networks and a communication carrier cooperates with another communication carrier to make a communication path redundant. In this system, a dedicated device (user access device) for carrier access is installed at a user base, and carrier switching is performed.

  Patent Document 1 further discloses redundancy of the control path of the user access device. The user access device can be connected to the communication device of the first carrier communication network and the communication device of the second carrier communication network. The user access device is managed by the first carrier management network via the first carrier communication device. When the management network of the first carrier and the user access device are connected at a single point, if the communication device of the first carrier that directly accommodates the user access device fails, the user access device becomes uncontrollable.

  In order to avoid this, Patent Document 1 proposes a multipoint connection between the user access device and the first carrier management network. Specifically, a method of making the first carrier communication device itself which directly accommodates the user access device redundant, a method of sending a control frame insertion command directly from the first carrier management network to the second carrier communication device, and A method is shown in which a control frame inserted in a normal communication device of one carrier is turned back by a user access device facing a user access device to be controlled.

JP 2009-219079 A

ITU-T Recommendation Y. 1731 IEEE 802.1ag ITU-T Recommendation G. 8031 / Y. 1342

  Thus, when a communication carrier provides a communication path redundancy service to a user, by using a plurality of communication apparatuses that accommodate user access devices and preparing different control paths via different communication apparatuses, the carrier management network Multi-point connection with the user access device can be realized, and the remote control path can be made redundant. As a result, it is possible to prevent remote control of the user access device from the carrier management network from being disabled due to a failure in one communication device.

  However, when the control path is made redundant in the communication network of the same communication carrier, one user access device belongs to at least two communication devices. Therefore, there is a possibility that a plurality of communication devices execute remote control operations of the user access device at the same time, resulting in contention for user access device settings. Therefore, when setting by remote control from the carrier management network to the user access device, it is necessary to select a route used for transmission of control information to the user access device in the redundant remote control route. In this route selection, it is important that an appropriate remote control route can be selected efficiently.

  A communication system according to an aspect of the present invention includes a user access device that communicates with the user terminal in access to the data communication network of the user terminal, and the user access device for the access of the user terminal to the data communication network. And a plurality of communication devices connectable to the data communication network. Each of the plurality of communication devices includes a control path for controlling the user access device with the user access device. The user access apparatus determines one control path that has been confirmed to be normal in the control paths of the plurality of communication apparatuses as an active control path, and determines another control path in the control paths of the plurality of communication apparatuses. It is determined as a control path for the standby system.

  According to the present invention, it is possible to efficiently determine an appropriate control path as the active control path in the redundant remote control path of the user access device.

It is a figure which shows typically the structural example of the communication system of this embodiment. It is a figure which shows the sequence chart explaining the example of the remote control path | route selection process from the initial state which the communication system of this embodiment implements. It is a figure which shows the example of the sequence chart explaining the remote control path | route selection process at the time of the failure generation | occurrence | production in the remote control path | route between the communication apparatus and user access apparatus which the communication system of this embodiment implements. It is a figure which shows the example of the sequence chart explaining the remote control path | route selection process at the time of the failure generation in the remote control path | route between the carrier management network and communication apparatus which the communication system of this embodiment implements. It is a figure which shows the example of the format of the communication frame which flows into the communication system of this embodiment. It is an example of the payload format of the control frame which flows into the communication system of this embodiment. In this embodiment, it is an example of the block diagram which shows the structure of a user access apparatus typically. In this embodiment, it is a flowchart explaining the example of the remote control path | route determination process from the initial state which a remote control path | route selection part performs. In this embodiment, it is a flowchart explaining the example of the remote control route determination process from the 0 system selection state which a remote control route selection part performs.

  Below, the form for implementing this invention is demonstrated. For clarity of explanation, the following description and drawings are omitted and simplified as appropriate. Moreover, in each drawing, the same code | symbol is attached | subjected to the same element and the duplication description is abbreviate | omitted as needed for clarification of description.

  FIG. 1 is a diagram schematically illustrating an example of a packet communication system according to the present embodiment. In this specification, the packet communication system means a communication system that divides and transfers data into data units, and is not limited to communication of data units in a specific layer (data link layer).

  The communication system illustrated in FIG. 1 is a communication system for providing a dedicated line service to a user with whom a communication carrier has signed a contract. The carrier communication network 2 performs user data communication, and data communication in the carrier communication network 2. And a carrier management network 18 for managing the network. Each of the user terminals 9 and 10 at the two user bases is connected (communication) to the carrier communication network 2 and communicates via it. In the present specification, unless otherwise specified, connection means communication connection, and means that communication is established.

  Each user site where the user terminals 9 and 10 exist is located between the user terminals 9 and 10 and the carrier communication network 2, and is on the user terminal side for connecting the user terminals 9 and 10 to the carrier communication network 2. User access devices 3 and 4 which are devices are arranged. Opposing user access devices 3 and 4 are connected to the carrier communication network 2 and communicate user data via the carrier communication network 2. The user access devices 3 and 4 communicate with the user terminals 9 and 10 via wiring or a network, respectively, and directly accommodate the user terminals 9 and 10.

  The user data communication path is made redundant in the carrier communication network 2, and the user access device 3 is connected to the opposite user access device 4 through two or more communication paths in the carrier communication network 2 (communication). can do. In this example, the user access devices 3 and 4 have an OAM (Operation Administration and Maintenance: Ethernet ITU-T recommendation Y.1731) and APS (Automatic Protection Switching: Ethernet ITU-T recommendation, for example, between them. G.8031).

  The communication devices 5 to 8 are devices on the communication network side for connecting the user terminals 9 and 10 to the carrier communication network 2. Each of the communication devices 5 and 6 can connect the user access device 3 to the carrier communication network 2 for data frame communication. The user access device 3 communicates a user frame with one communication device selected from them.

  Similarly, the user access device 4 can be connected to the communication device 7 and the communication device 8 of the carrier communication network 2 for data frame communication, and the user access device 4 can transmit a user frame to one communication device selected from them. connect. The user access devices 3 and 4 are connected to the carrier communication network 2 in the selected communication device. The communication path between the user access devices 3 and 4 and the communication devices 5 to 8 may be a physical line or a communication network.

  In this configuration example, two communication paths are prepared between the user access devices 3 and 4. The active communication path is a communication path that passes through the user access device 3, the communication device 5, the communication device 7, and the user access device 4. The standby communication path is a communication path that passes through the user access device 3, the communication device 6, the communication device 8, and the user access device 4. One communication path is normally used as an active system. The other path is a standby system, and is switched from the active system to the standby system when a failure occurs in the active system. The carrier communication network 2 may prepare a communication path different from these.

  In this example, each user access device 3, 4 confirms the normality of the carrier communication network 2 using an OAM CCM (Connectivity Check Message) frame in Ethernet.

  If the user access device cannot receive the CCM frame from the opposite user access device (CCM frame is not received) and detects a disconnection of the carrier communication network 2, a communication path capable of continuing communication in the carrier communication network 2 is selected. , APS switches the route. Thereby, the communication between the user terminals 9 and 10 is made redundant, and a highly reliable dedicated line service can be provided. The above is the path redundancy method for the user frame.

  Further, the communication system shown in FIG. 1 illustrates a remote control path for the user access device 3. The user access device is a device for carrier access provided from a communication carrier, and is controlled and managed by the communication carrier. The carrier management system 1 in the carrier management network 18 controls the user access device 3.

  In the communication system of this embodiment, the remote control paths of the user access devices 3 and 4 are also made redundant. These configurations are the same, and the remote control path of the user access device 3 will be described below. Only the remote control path of the user access device 3 may be made redundant.

  Remote control paths are set between the user access device 3 and the communication device 5 and between the user access device 3 and the communication device 6. The carrier management system 1 can transmit a control frame to the user access device 3 via the communication devices 5 and 6 and can control the user access device 3. In this configuration example, the carrier management system 1 performs in-band remote control using the same communication network as user data.

  The carrier management system 1 instructs remote control of the user access device 3 to all communication devices to which the user access device 3 belongs. That is, the carrier management system 1 transmits a control frame instructing control of the user access device 3 to the communication devices 5 and 6. It is necessary to select one of the control path of the communication apparatus 5 and the control path of the communication apparatus 6 in order to prevent both of the communication apparatuses 5 and 6 receiving the control frame from controlling the user access apparatus 3. It is.

  In the present embodiment, the user access device 3 selects one control path as a working control path from among the redundant remote control paths. Further, the user access device 3 selects one control path whose normality has been confirmed as an active control path. In this way, the user access device 3 determines one control path as the active system and determines the other control path as the standby system, so that a normal control path can be efficiently selected.

  In this configuration example, the user access device 3 and the communication device 5 and the user access device 3 and the communication device 6 perform Ethernet level OAM in a remote control path between them. The user access device 3 and the communication device 5 and the user access device 3 and the communication device 6 confirm the normality of the remote control path by the CCM frame.

  In a preferred configuration, the user access device 3 monitors the reception of the CCM frame between the connected communication devices 5 and 6, sets the remote control path whose normality has been confirmed earlier as the active system (ACT), and later as normal. The remote control path that has been confirmed to be sex is determined as a standby system (SBY). By selecting a remote control path whose normality has been confirmed first as an active system, it is possible to avoid a long time for processing and to quickly start remote control (determine a remote control path).

  The user access device 3 further transmits the remote control route selection result to each of the communication devices 5 and 6 by using a control frame using a VSP (Vendor Specific OAM) that implements a message exchange unique to the device vendor. Notifications 1023 and 1033 of (determination results) are transmitted.

  As described above, the remote control instruction from the carrier management system 1 to the user access device 3 is given to the communication device 5 and the communication device 6. In the example shown in FIG. 1, the user access device 3 has selected the remote control path of the communication device 5 as the active system. Typically, the active communication device for remote control is the same as the active communication device for user data communication. These may be different.

  As described above, when the remote control path from the communication device 5 of the communication carrier (referred to as a 0-system route) is ACT, the communication device 5 receives a control frame insertion command from the carrier management system 1 to the user access device 3. The request control frame 1024 is transmitted to the user access device 3.

  The payload of this request control frame 1024 includes information that the device that is the destination address terminates this frame. The contents of the request control frame 1024 are instructed by the carrier management system 1. The user access device 3 that has received the request control frame 1024 analyzes the control frame.

  When the user access device 3 confirms that the request control frame 1024 is addressed to itself and that the control frame is terminated, the user access device 3 terminates the request control frame 1024 and reflects device settings and the like. The user access device 3 transmits a response control frame 1025 to the communication device 5 as a response to the request control frame 1024.

  On the other hand, a remote control path (referred to as a 1-system path) from the carrier communication device 6 is a standby system (SBY). Even when the communication device 6 receives a control frame insertion command from the carrier management system 1 to the user access device 3, the communication device 6 ignores the command and does not perform the process of transmitting the control frame to the user access device 3.

  In this way, in the redundant remote control path, one remote control path (0-system path) that has confirmed that the user access device 3 is normal is selected as the ACT system path, and the other remote control path ( 1 system route) is selected as the SBY system route, so that double setting and conflict setting of the user access device 3 can be prevented, and a remote control route suitable for control of the user access device 3 can be efficiently selected. it can.

  Next, an outline of remote control path selection of the user access device 3 using the CCM frame in the communication system of the present embodiment will be described with reference to FIG. FIG. 2 is a sequence diagram showing remote control route selection processing in the communication system of the present embodiment.

  The user access device 3 is under the management of a communication carrier. First, the carrier management system 1 performs user access device registration processing (1000) for the communication devices 5 and 6. In the processing, the carrier management system 1 transmits a registration command to each of the communication devices 5 and 6 (1011 and 1013).

  Receiving the registration command, each of the communication devices 5 and 6 registers the information of the user access device 3 included in the received registration command in its own storage device. As a result, the user access device 3 is registered as a user access device accommodated in the communication devices 5 and 6. Each of the communication devices 5 and 6 transmits a registration command response to the carrier management system 1 as a response to the received registration command (1012, 1014).

  Thereafter, the communication devices 5 and 6 respectively transmit CCM frames addressed to the registered user access device 3 (1021 and 1031), and monitor the CCM frame response from the user access device 3 to monitor the remote control path. Perform health monitoring.

  In the initial state 1040 of the user access device 3, the remote control path is not set. Similarly, the communication devices 5 and 6 are in a state where the remote control path is not set. The communication devices 5 and 6 may be in the SBY state before the remote control path is set.

  In this state, the user access device 3 receives the CCM frame addressed to itself, and starts a new remote control path determination process. Specifically, the user access device 3 monitors reception of the CCM frame (1021, 1031) addressed to itself, normality of the remote control path with the communication device 5, and remote control with the communication device 6. Check the normality of the route.

  For example, when the user access device 3 continuously receives the same CCM frame addressed to itself N times (N = 5 in an example), the user access device 3 establishes a remote control path with the communication device and determines that it is normal. In the example of FIG. 2, the user access device 3 receives N consecutive CCM frames from both the communication device 5 and the communication device 6 (1041), and the remote control path between the communication device 5 and the communication device 6 It is determined that both of the remote control paths are normal.

  Next, the user access device 3 selects the first established remote control path as the remote control path of the ACT system according to the order in which the remote control paths are established (order determined to be normal) (1042). In this example, it is assumed that the 0-system remote control path is established first (first). The user access device 3 determines another remote control path established later, in this example, the 1-system remote control path as the SBY-based remote control path.

  The user access device 3 responds with a CCM frame to each remote control route established between the communication devices 5 and 6 (1022, 1032), and the remote control route selection result is communicated to each communication using a control frame using the VSP. Notify the devices 5 and 6. In this example, since the 0-system remote control route is established first, the user access device 3 transmits a control route notification (ACT) to the communication device 5 by a control frame (1023). A control route notification (SBY) is transmitted by the control frame (1033).

  For example, when the communication device 5 receives the CCM frame addressed to itself from the user access device 3 continuously M times (M = 5 in an example) (1022), the remote control path with the user access device 3 is established. (1020). The communication device 5 further receives the control route notification (ACT) from the user access device 3 (1023), thereby recognizing that the remote control route from the own device is an ACT system (1027).

  The communication device 5 that has recognized that the remote control path from its own device is the ACT system transmits a request control frame reflecting the remote control information for the user access device 3 from the carrier management system 1 to the user access device 3 ( 1024).

  The user access device 3 receives the request control frame from the communication device 5 and terminates the received request control frame. The user access device 3 transmits a response control frame addressed to the communication device 5 as a response to the request control frame (1025). The communication device 5 terminates the response control frame received from the user access device 3, and notifies the carrier management system 1 that registration of the user access device 3 has been completed normally (1026).

  Similarly to the communication device 5, the communication device 6, when receiving the same CCM frame 1032 addressed to itself from the user access device 3 M times (M = 5 in one example) continuously, remote control with the user access device 3. It recognizes that the route has been established (1030). Further, the communication device 6 receives the control route notification (SBY) from the user access device 3 (1033), and recognizes that the remote control route from the own device is the SBY system (1035).

  The communication device 6 that has recognized that its own remote control path is the SBY system performs the process of reflecting the remote control information from the carrier management system 1 to the user access device 3 (transmission of a request control frame reflecting the remote control information). In step 1034, the carrier management system 1 is notified of the successful registration of the user access device.

  As described above, the setting processing of the active remote control circuit is performed between the user access device 3 and the communication devices 5 and 6, and the carrier management system 1 is not involved. Further, the carrier management system 1 does not need to know the working path in the control of the user access device 3. Thereby, the process of the whole system and the carrier management system 1 can be reduced.

  As can be understood from the above description, the user access device 3 can check the normality of both (all) of the two remote control paths. The user access device 3 that directly confirms the normality of the two remote control paths selects the ACT remote control path, so that the active remote control path can be selected efficiently.

  In the above process, each of the communication devices 5 and 6 sets the remote control path to the ACT system state or the SBY system state in accordance with an instruction from the user access device 3. Since the user access device 3 determines the state of each remote control path, it is efficient for the user access device 3 to notify the communication devices 5 and 6 of the setting. Depending on the design, another device, for example, one communication device may indicate the state of the remote control path to the other communication device.

  As described above, it is preferable that the user access device 3 determines the remote control path whose normality has been confirmed earliest as the active path. Depending on the design, priority may be given to each remote control path in advance. For example, the user access device 3 selects the route with the highest priority as the ACT route in the remote control route that has been confirmed to be normal within a specified time.

  In the above example, the communication devices 5 and 6 notify the carrier management system 1 that the registration of the user access device has been normally completed. In addition, the communication devices 5 and 6 may notify the status of the own device for remote control. Good. In the above example, the communication device 5 notifies that it is in the ACT state, and the communication device 6 notifies that it is in the SBY state.

  In the initial state before the control path with the user access device 3 is established, when the communication devices 5 and 6 are in the SBY state, the user access device 3 is only in the communication device of the control path determined to be the ACT system. A setting instruction may be issued, and a state setting instruction to the communication device of the control path determined as the other standby system may be omitted. Even in such a configuration, the user access device 3 sets the state in all communication devices including the standby communication device in order to reliably avoid that the communication device not used as the active control path is in the ACT type state. The command may be transmitted.

  Next, an overview of remote control path selection performed by the communication system of the present embodiment when a failure occurs in the remote control path between the communication apparatus and the user access apparatus will be described using the sequence diagram of FIG. . When a failure occurs in the active (ACT) remote control path with the communication apparatus 5, the user access apparatus 3 switches to another remote control path (control path with the communication apparatus 6) whose normality has been confirmed. Switch the active remote control route.

  As shown in FIG. 3, the user access device 3 is in the 0 system selection state (1140), the communication device 5 (the remote control route) is in the ACT state (1120), and the communication device 6 (the remote control route) is in the SBY state. (1130). The communication apparatuses 5 and 6 and the user access apparatus 3 periodically exchange CCM frames (1123, 1132, 1124, 1133). If the CCM frame is not received for a predetermined period (a predetermined number of cycles), the communication devices 5 and 6 and the user access device 3 determine that a failure has occurred in the control path.

  For example, when the user access device 3 does not receive the same CCM frame addressed to itself from the communication device 5 or the communication device 6 L times (L = 3 in one example) (1150), the user access device 3 It is determined that (Loss Of Continuity) has occurred, and it is determined that a failure exists in the remote control path with the communication device (failure detection).

  In this example, since the user access device 3 did not receive three consecutive CCM frames from the communication device 5, it detects that no CCM frame has been received in the 0 system of the remote control path, and accordingly, the 0 system remote control path Is recognized (1141).

  The user access device 3 confirms that the remote control path of the first system that is the standby remote control path is normal, and changes the remote control path to be used (the active remote control path) from the 0-system remote control path to 1 Switch to the system remote control path (1142). As described above, the user access device 3 periodically communicates the CCM frame with the communication device 6 to confirm that the 1-system remote control route that is the control route is normal.

  Next, the user access device 3 transmits a control path notification (ACT) to the communication device 6 using the control frame (1134). The user access device 3 further transmits a control route notification (SBY) to the communication device 5 (output of a control route notification (SBY) addressed to the communication device 5) (1125). This control path notification (SBY) may not reach the communication device 5 due to a failure.

  Similarly to the user access device 3, each of the communication devices 5 and 6 recognizes that a LOC has occurred when the same CCM frame addressed to itself has not been received L times consecutively (L = 3 in one example). 3, it is determined that a failure has occurred in the remote control path.

  The communication device 5 recognizes the failure of the remote control path from the own device by detecting that the CCM frame has not been received (1121), and transmits a communication alarm occurrence notification to the carrier management system 1 (1126). Further, the communication device 5 changes the state of the remote control path of the own device from the ACT system to the SBY system (1122).

  On the other hand, the communication device 6 receives a control frame from the user access device 3 (1134). The communication device 6 recognizes that the remote control path from the own device is switched from the SBY system to the ACT system by this control frame. The communication device 6 changes the state of the remote control path from the SBY system to the ACT system (1131).

  Thereafter, the communication device 6 controls the user access device 3 in accordance with a remote control instruction from the carrier management system 1. The above is the remote control path selection (switching) method when a failure occurs in the remote control path between the communication device and the user access device. Thereby, even if a failure occurs between the communication device and the user access device, it is possible to prevent the remote control from the carrier management system 1 to the user access device 3 from being disabled. Further, it is possible to eliminate the involvement of the carrier management system 1 in switching the remote control path.

  As described above, the communication device 5 in which a failure in the control path has occurred (detected) itself changes from the ACT system state to the SBY system state without an instruction from another device. In general, when a failure occurs in the control path, a command from the user access device 3 does not reach the communication device 5. When the communication device 5 changes itself to the SBY state, when the failure is removed and the control path is recovered, the double setting or the conflict setting of the user access device 3 can be prevented more reliably.

  In the above configuration, the user access device 3 determines the switching of the control path and the switching destination. Since the user access device 3 knows the state of each control path (whether there is a failure), the control path switching process can be performed efficiently and quickly. Similarly, it is possible to perform the control path switching process efficiently and quickly that the user access device 3 instructs the communication device 6. Depending on the design, another device may instruct the communication device 6.

  Depending on the design, the communication device 5 may maintain the ACT state or may transition to the SBY state according to a command from the carrier management system 1. However, in order to surely prevent the double setting and the conflict setting and make the processing of the carrier management system 1 unnecessary, it is preferable that the communication device 5 performs the state transition itself.

  In the above configuration, the user access device 3 transmits a control route notification (SBY) to the communication device 5 in which a failure has occurred in the control route (including the communication device 5). As a result, it is possible to further reduce the possibility that the communication device 5 maintains the ACT state for some reason and the double setting or the conflict setting occurs due to the subsequent failure recovery.

  As described above, it is preferable that the user access device 3 always performs failure monitoring not only on the control path to the ACT communication device 5 but also on the control route to the SBY communication device 6. As a result, when a failure occurs in the ACT system control path, the remote control path to be used can be immediately switched to the SBY system control path.

  The communication devices 5 and 6 may notify the carrier management system 1 when the state of the remote control path is changed. When three or more remote control paths are prepared, the user access device 3 can select any control path of the SBY system as a switching destination. When the priority is given to the remote control route in advance, the control route with the highest priority is selected.

  Next, an overview of remote control path selection (switching) for the user access device 3 performed by the communication system of the present embodiment when a failure occurs between the carrier management network and the communication device, using the sequence diagram of FIG. Will be explained. Each communication device 5, 6 transmits a monitoring frame to the carrier management system 1, and further confirms the return, thereby generating a failure in the control path between the carrier monitoring network 1 and each communication device 5, 6. Can be detected.

  As shown in FIG. 4, it is assumed that the user access device 3 is in the 0 system selection state 1240, the control path of the communication device 5 is the ACT state 1220, and the communication device 6SBY system state 1230. Each of the communication devices 5 and 6 periodically transmits a monitoring frame to the carrier management system 1 (1225 and 1233), and confirms the return of the control frame to confirm the normality of each control path (1221 and 1231). ).

  If the ACT communication device 5 cannot detect the return of the monitoring frame due to a communication failure 1250 or the like (1222), it determines that a failure has occurred in the remote control path between the communication device 5 and the carrier management system 1. (1223).

  The communication device 5 that has determined that a failure has occurred transmits a request control frame reflecting the remote control path switching instruction information to the user access device 3 to the user access device 3 (1226). The user access device 3 terminates the received request control frame (1226). Further, as a response, a response control frame addressed to the communication device 5 is transmitted (1227).

  The user access device 3 confirms that the remote control path of the first system that is the standby remote control path is normal, and changes the remote control path to be used (the active remote control path) from the 0-system remote control path to 1 Switch to the system remote control path (1241). As described above, the user access device 3 periodically communicates the CCM frame with the communication device 6 to confirm that the 1-system remote control route that is the control route is normal.

  Next, the user access device 3 transmits a control path notification (ACT) to the communication device 6 using the control frame (1233). The user access device 3 further transmits a control route notification (SBY) to the communication device 5 (1228). When receiving the control frame from the user access device 3 (1228), the communication device 5 changes the state of the remote control path from the own device from the ACT system to the SBY system (1224).

  The communication device 6 recognizes that the remote control path from its own device is switched from the SBY system to the ACT system by receiving the control frame from the user access device 3 (1233). The communication device 6 changes the state of the remote control path from the SBY system to the ACT system (1232). Thereafter, the communication device 6 controls the user access device 3 in accordance with a remote control instruction for the user access device 3 from the carrier management system 1.

  The above is the method for selecting a remote control route when a failure occurs in the remote control route between the carrier management network and the communication device. When a failure occurs in the ACT route between the carrier management network and the communication device, the user access device 3 cannot be remotely controlled from the carrier management system 1 by switching to the normal SBY route due to the failure. Can be prevented.

  In the above configuration, the user access device 3 instructs each of the communication devices 5 and 6 to change the state of the control path in accordance with an instruction from the communication device 5 that has detected the failure. Like the sequence described with reference to FIG. 3, the communication device 5 may switch its state by itself. Even in that case, the user access device 3 may transmit a control path notification (SBY) to the communication device 5. As a result, the same process as the sequence of FIG. 3 is performed. Since the user access device 3 issues a command to the communication device 6 in common with other sequences, the overall processing becomes simple. Depending on the design, the communication device 5 or the carrier management system 1 may instruct the communication device 6.

  As described above, it is preferable that not only the ACT communication device 5 but also the SBY communication device 6 always perform failure monitoring on the control path between the carrier management system 1 and the SBY communication device 6. As a result, when a failure occurs in the ACT system control path, the remote control path to be used can be immediately switched to the SBY system control path. If a failure has occurred in the communication device 6, the communication device 6 may respond to the reception of the control frame from the user access device 3 (1233) and send a response to that effect. Alternatively, the user access device 3 may be notified in advance of the occurrence of a failure.

  When three or more remote control paths are prepared, the user access device 3 can select any one control path from the normal remote control paths. When failure information of each control path is acquired in advance, one control path is selected from normal remote control paths with reference to the information. When priority is given to each remote control route, a normal control route having the highest priority is selected. The communication devices 5 and 6 may notify the carrier management system 1 when the state of the remote control path is changed.

  Hereinafter, a format example of a communication frame in the communication system according to the present embodiment will be described with reference to FIGS. 5 and 6. The communication frame described here includes a control path notification (ACT), a control path notification (SBY), a request control frame, and a response control frame.

  As illustrated in FIG. 5, an example of a frame used in the communication system includes a destination MAC address 401, a transmission source MAC address 402, a VLAN header 403, a MAC header including an ether type value 404 indicating the type of the subsequent header, It consists of a payload 405 and a frame check sequence (FCS) 406.

  In the destination MAC address 401 and the transmission source MAC address 402, any one of the MAC addresses of the user terminals 9, 10, the user access devices 3, 4, and the communication devices 5-8 is set. A VLAN header 403 indicates a VLAN ID value (VID #) that is a flow identifier.

  FIG. 6 shows an example of the format of the payload 405 of the control frame described with reference to FIG. As described above, in the communication system, the user access devices 3 and 8 and further the communication devices 5 to 8 are devices that can implement OAM and APS for Ethernet.

  In addition to the above-mentioned CCM frame and AIS (Alarm Indication Signal) for notifying other devices of the occurrence of an error, Ethernet OAM defines VSP (Vendor Specific OAM) that implements device vendor-specific message exchange. . Since the VSP can be used for a vendor-specific purpose, the VSP can be used for remote control of the communication system. Therefore, the control frame has a VSP format.

  In this example, the payload 405 of the control frame includes an MEG (Maintenance Entity Group) level 4051, Version: 4052, OpCode: 4053, a flag 4054, a TLV offset 4055, an OUI (Organizationally Unique Code 57, 40). And TLV (control information) 4058 and End TLV 4059.

  In the MEG level 4051, a level for performing OAM determined by the carrier is set, and in the version 4052, the OAM version is set. In OpCode 4053, a value indicating the type of OAM message is set. In the case of VSP, “51” is set for VSM (VSP Message: request control frame), and “50” is set for VSR (VSP Reply: response control frame). The flag 4054 is an area that can be used independently by the vendor, and its content is not determined by the recommendation.

  The TLV offset 4055 indicates the length of the fixed area up to the TLV and can be determined independently by the vendor. For example, a value “4” obtained by adding the lengths of the OUI 4056 and the SubOpCode 4057 is set. The OUI 4056 indicates an organization (vendor) ID. Although the value is not defined in the recommendation, “0” is set in one example.

  SubOpCode 4057 indicates the type of VSP frame, and its content is not defined in the recommendation, but is used as a field indicating a control frame transfer processing method in this system. “0” is set for the end, and “1” is set for the loopback. In this system, values other than those described above are not set in the SubOpCode 4057. A TLV 4058 is a payload of a control frame and can be freely used by a vendor. However, control information is stored in this system. Finally, End TLV 4059 indicates the end of the payload of the control frame, and “0” is set.

  Next, the configuration of the user access device 3 will be described with reference to FIG. FIG. 7 is a diagram schematically showing the configuration of the user access device 3. The user access device 3 includes communication device IF units 100a and 100b, a remote control route determination unit 11, a command selection unit 12, a command processing unit 13, a device alarm collection unit 14, user frame selection units 15 to 16, and a user terminal IF unit 17 It has.

  The communication device IF units 100a and 100b are interfaces for transmitting and receiving signals to and from the communication device. The user access device 3 includes a 0-system communication device IF unit 100a and a 1-system communication device IF unit 100b because of a redundant configuration. In the communication device IF units 100a and 100b, components having the same name have the same function. In the following, the communication device IF unit 100a will be described.

  In the communication apparatus IF unit 100a, the Ethernet IF unit 101a has a function of transmitting and receiving a user frame and an Ethernet OAM frame. The receiving unit 105a determines whether the frame received from the Ethernet IF unit 101a is a user frame or a control frame. If the frame is a user frame, the receiving unit 105a sends the frame to the user frame selection unit 16; A function of sending to the unit 104.

  The control frame termination unit 104a terminates the received control frame, transmits a remote control instruction command from the communication device to the command selection unit 12, performs reception monitoring of the CCM frame addressed to itself, detects LOC, and detects OAM. An RDI (Remote Defect Indication) frame detection function is provided.

  The control frame generation unit 103a has a function of generating a control frame for notifying or responding to the communication apparatus and transmitting the control frame to the transmission unit 102a. The transmitting unit 102a has a function of multiplexing frames received from the user frame selecting unit 15 and the control frame generating unit 103a and transmitting the multiplexed frames to the Ethernet IF unit 101a.

  In the following, components other than the communication device IF units 100a and 100b will be described. The remote control path determination unit 11 selects a remote control path based on the information acquired from the control frame end units 104a and 104b and the device alarm collection unit 14, and sends the selection result to the control frame generation unit 103 and the command selection unit 12. It has a function to transmit.

  The command selection unit 12 has a function of selecting a remote control instruction command transmitted from the control frame termination units 104 a and 104 b according to an instruction from the remote control path determination unit 11 and transmitting the command to the command processing unit 13. The command processing unit 13 has a function of terminating the remote control instruction command received from the command selection unit 12.

  The device alarm collection unit 14 has a function of monitoring the link state of the physical port of the user access device 3 and collecting device alarms. The user frame selection unit 15 has a function of transmitting the user frame received from the user terminal IF unit 17 to the transmission unit (102a or 102b) of the system selected according to the device setting.

  The user frame selection unit 16 has a function of transmitting, to the user terminal IF unit 17, a user frame of a system selected according to the device setting in the user frames received from the reception units 105 a and 105 b. The user terminal IF unit 17 is an interface for transmitting and receiving signals to and from the user terminal, and has a function of transmitting and receiving user frames.

  Next, a process in which the user access device 3 in the initial state selects an ACT remote control path (a process for determining the state of each control path) will be described with reference to the flowchart of FIG. This process can be applied to the sequence described with reference to FIG. The remote control route determination unit 11 in the user access device 3 executes this selection process (determination process).

  FIG. 8 shows a flowchart of the remote control route determination process 200 in the initial state by the remote control route determination unit 11. The remote control path determination unit 11 includes information from the control frame termination units 104a and 104b (normal LOC, no RDI occurrence, failure LOC, RDI occurs) and information from the device alarm collection unit 14 (normal physical port link). Normal failure information is acquired from (Up, failure physical port link down) (S201).

  The remote control path determination unit 11 determines the remote control path based on the acquired normal failure information. Specifically, first, the normality of the 0-system remote control path (control path to the communication device 5) is confirmed (S202). When the 0-system remote control path is normal (YES in S202), the remote control path determination unit 11 selects the 0-system as the remote control path and instructs the control frame generation unit 103 to generate a control frame (S203). . Further, the remote control route determination unit 11 instructs the command selection unit 12 to select the 0 system (S204). Thereafter, the remote control route selection process is terminated (S208).

  When a fault exists in the 0-system remote control path (NO in S202), the remote control path determination unit 11 checks the normality of the 1-system remote control path (control path to the communication device 6). Perform (S205). When the remote control path of system 1 is normal (YES in S205), remote control path determination unit 11 selects system 1 as the remote control path and instructs control frame generation unit 103 to generate a control frame (S206). .

  Further, the remote control route determination unit 11 instructs the command selection unit 12 to select the first system (S207), and ends the remote control route selection process (S208). If there is a failure in the 1-system remote control path (NO in S205), the remote control path determination unit 11 executes the remote control path determination flow from step 201 again.

  Next, referring to FIG. 9, the user access device 3 switches the ACT-based remote control path from the 0-system remote control path to the 1-system remote control path (process for determining the state of each control path). ). This process can be applied to the sequence described with reference to FIG. 3 or FIG. The remote control route determination unit 11 in the user access device 3 executes this selection process (determination process).

  FIG. 9 shows a flowchart of the remote control route determination processing 300 by the user access device 3 in the 0 system selection state. The remote control path determination unit 11 acquires normal failure information from the control frame termination units 104a and 104b and the device alarm collection unit 14 (S301). The remote control path determination unit 11 determines the remote control path based on the acquired normal failure information.

  Specifically, the remote control path determination unit 11 first checks the normality of the 0-system remote control path that is the selection system (S302). If a failure has occurred in the 0-system remote control path (NO in S302), the remote control path determination unit 11 checks the normality of the 1-system remote control path, which is a non-selected system (S303). When the 1-system remote control path is normal (YES in S303), the remote control path determination unit 11 selects the 1-system remote control path as the ACT-system remote control path.

  The remote control path determination unit 11 instructs the control frame generation unit 103 to generate a control frame (S304), and further instructs the command selection unit 12 to select one system (S305). Thus, the remote control route selection process is completed (S307).

  When the 0-system remote control path is normal (YES in S302), the remote control path determination unit 11 executes the remote control path determination flow from step 301 again. If a failure has occurred in the 1-system remote control path (NO in S303), the remote control path determination unit 11 transitions to an initial state (S306) and ends the remote control path selection process (S307). The transition to the initial state means the transition to the initial state remote control route selection process described with reference to FIG.

  As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to said embodiment. A person skilled in the art can easily change, add, and convert each element of the above-described embodiment within the scope of the present invention. In the above configuration, the user data path and the control path exist on the same physical line, but they may be transmitted through different physical lines.

  In selecting the active control path from the initial state, the user access device performs normality confirmation processing (normality check) on only a part of the control paths (one in the above example) and confirms that it is normal. If it is possible, it may be selected as the control path for the active system. As described above, the system preferably performs failure detection and control path switching also in the control path between the carrier management network 18 and the carrier communication network 2, but the function may be omitted depending on the design.

  The present invention is suitable for remote control of a user access device from a management system, but the communication device can also be applied to a system that directly controls a user access device without an instruction from the management system. The access device may be controlled. The present invention is suitable for communication control in the second layer, particularly Ethernet, but the present invention can be applied to communication control in other communication protocols.

  The present invention can be applied to a system including two or more types of carrier communication networks. In this configuration, the plurality of types of carrier communication networks constitute one data communication network for transferring user data. The present invention can be applied to a system that provides a service different from a dedicated line.

DESCRIPTION OF SYMBOLS 1 Carrier management system 2 Carrier communication network 3, 4 User access apparatus 5, 7, 6, 8 Communication apparatus 9, 10 User terminal 11 Remote control route determination part 12 Command selection part 13 Command processing part 14 Device alarm collection parts 15, 16 User frame selection unit 17 User terminal IF unit 18 Carrier management network 100a, 100b Communication device IF unit 101a, 101b Ethernet IF unit 102a, 102b Transmission unit 103a, 103b Control frame generation unit 104a, 104b Control frame termination unit 105a, 105b Reception unit

Claims (12)

A user access device that communicates with the user terminal in accessing the data communication network of the user terminal;
A plurality of communication devices capable of connecting the user access device to the data communication network for the access of the user terminal to the data communication network;
Each of the plurality of communication devices includes a control path for controlling the user access device with the user access device,
The user access apparatus determines one control path that has been confirmed to be normal in the control paths of the plurality of communication apparatuses as an active control path, and determines another control path in the control paths of the plurality of communication apparatuses. A communication system that determines a control path for a standby system.   The user access device performs normality confirmation processing for each of the control paths of the plurality of communication devices, and determines a control path that is initially confirmed to be normal as the active control path. The communication system according to 1.   In response to the determination of the occurrence of a failure in the active control path, the user access device determines one control path that has been confirmed to be normal in the standby control path as a new active control path. The communication system according to claim 1 or 2.   The communication system according to claim 3, wherein the working communication device changes the state of the control path of the own device from the working system to the standby system in response to the determination of the occurrence of a failure in the working control path. The communication system further comprises a management system for managing the user access device,
The plurality of communication devices receive a control command for the user access device from the management system,
The working communication device controls the user access device according to the command,
The standby communication device ignores the command,
When a failure occurs in the control path between the active communication apparatus and the management system, the user access apparatus uses one control path of the standby control path as a new active control path. The communication system according to claim 1, wherein the communication system is determined.   The communication system according to claim 3, wherein the user access device transmits a data unit that instructs the active communication device to switch the control path from the active system to the standby system.   The communication system according to claim 1, wherein each of the user access device and the plurality of communication devices performs failure monitoring on the active control path and the standby control path.   The communication system according to claim 5, wherein the management system and the plurality of communication devices monitor a failure of a control path between them. In a communication system, a method for controlling a user access device between a user terminal and a data communication network for connecting the user terminal to the data communication network,
In the user access device, one of the plurality of control routes that transmit the control data unit to the user access device is determined as a normal control route that is confirmed as normal,
In the user access device, a control path other than the one control path in the plurality of control paths is determined as a standby control path,
A method of transmitting, to the user access device, a control data unit for controlling the user access device via the active control path.   10. The user access device performs normality confirmation processing for each of the control paths of the plurality of communication devices, and determines a control path that has been confirmed to be normal first as the active control path. The method described in 1.   In the user access device, in response to the determination of the occurrence of a failure in the active control path, one control path that has been confirmed to be normal in the standby control path is determined as a new active control path. The method according to claim 9 or 10.   12. The method according to claim 9, 10 or 11, wherein fault monitoring is performed on the active control path and the standby control path.

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