JP6278869B2 - NE management apparatus and configuration synchronization method - Google Patents

Description

The present invention relates to a technology for synchronizing a configuration between redundant network devices (NE: Network Element), and in particular, in an N + m redundant configuration in which N active NEs share m spare NEs. performing configuration of synchronization when switching to the protection NE from the active NE, about the NE management device and configuring the synchronization how.

  In today's widespread use of the Internet, services for corporate users such as VPN (Virtual Private Network) services and wide area LAN (Local Area Network) services, ISP (Internet Service Provider) connection services, and personal users such as PCC (PC Communicator) services Various communication services are provided, such as services for customers. It is known that necessary information is automatically set for the NE as a means for a communication carrier such as ISP to provide these services to the user (see Non-Patent Document 1).

  The means described in Non-Patent Document 1 starts when an operator accepts an application for a service from a user and registers the information in a business system upper operation system (upper OpS). The host OpS registered with the service application information transmits a service order (SO: Service Order) to the order entry system. Here, the service order (SO) includes, for example, service information (VPN, PCC, etc.), order information (new contract, cancellation), user information, and the like.

  Upon receiving the service order, the order entry system analyzes and sorts the service order, and inputs (sends) the service order as a command to the NE related to the applied service. The NE is set by rewriting a config (Config) held by itself based on the service order that has been input. The NE can be set for each service and each user.

  In addition, in order to realize high solubility and operability of the network, N working NEs and m (N> m) spare NEs are used, and the N working NEs are shared by the m spare NEs. An N + m redundant configuration is known. Then, it has been proposed that the management function unit (NE management device (EMS: Element Management System)) concentrates on failure detection and switching from the current NE to the standby NE (see Non-Patent Document 2).

Hiroaki Sakata et al., “Reduction of order processing time in large-scale IP networks”, The Institute of Electronics, Information and Communication Engineers, 109, 463 (ICM2009 45-71), pages 105-110 Junji Nakatsumi et al., “Network Edge System Configuration Method with High Availability and Operability”, The Institute of Electronics, Information and Communication Engineers, 111, 8 (NS2011 1-15), 31-36

  Here, in the technique described in Non-Patent Document 2, since which active NE is switched to which spare NE is not determined until the switching time, the configuration of the current NE before switching and the standby after switching are determined at the switching time. It is necessary to synchronize with the NE configuration.

  However, Non-Patent Document 2 does not propose a specific means for synchronizing the configuration of the current NE before switching and the configuration of the standby NE after switching. For this reason, it is difficult to synchronize the configuration when switching NEs.

The present invention has been made in view of the above problems, it is possible configuration synchronization between redundant network device, and to provide an NE management device and configuring the synchronization how.

In order to solve the above-mentioned problem, the NE management apparatus according to the present invention is communicably connected to a working NE constituting a network and a spare NE used as a spare for the working NE, and inputs a service order to the working NE. And a NE management apparatus for switching from the working NE to the spare NE, the storage unit storing a spare base configuration in which information for identifying the spare NE is set, and the working NE A stored SO storage unit that stores a service order that has been input to the storage unit, and a standby unit that inputs the spare base configuration to the spare NE when switching from the current NE to the spare NE A BC input unit, and an input SO re-input unit for inputting the already-entered service order to the spare NE. The features. Here, the base configuration is setting information at the time of start-up, for example, information on only device information (such as the IP address of the device itself) that does not reflect the service order.

  By doing so, the NE management apparatus according to the present invention owns the base configuration (BC) of the spare NE and the service order already input to the current NE 5 on its own (NE management apparatus side), and at the time of switching These pieces of information are sequentially input to the spare NE. Therefore, the configuration can be synchronized between the switching-source active NE and the switching-destination standby NE. Further, since the NE management device manages the base configuration (BC) and service orders of all the spare NEs, the accommodation of the users accommodated by the current NE can be easily executed. For example, in addition to the failure of the working NE (for example, when the resources of the working NE are imminent), it is possible to replace part of the users accommodated by the working NE with the spare NE.

According to the NE management device and configuring the synchronization how according to the present invention, it is possible configuration synchronization between redundant network device.

1 is an overall view (normal time) of a configuration synchronization system according to a first embodiment of the present invention. 1 is an overall view (at the time of failure) of a configuration synchronization system according to a first embodiment of the present invention. It is a functional block diagram of the NE management apparatus which comprises the configuration synchronization system which concerns on 1st Embodiment of this invention. It is a business flow using the configuration synchronization system according to the first embodiment of the present invention. It is a flowchart of the NE management apparatus which comprises the configuration synchronization system which concerns on 1st Embodiment of this invention. It is a general view (normal time) of the configuration synchronization system which concerns on 2nd Embodiment of this invention. It is a general view (at the time of a failure) of the configuration synchronization system which concerns on 2nd Embodiment of this invention. It is a functional block diagram of the NE management apparatus which comprises the config synchronous system which concerns on 2nd Embodiment of this invention. It is a business flow using the configuration synchronization system which concerns on 2nd Embodiment of this invention. It is a flowchart of the NE management apparatus which comprises the configuration synchronization system which concerns on 2nd Embodiment of this invention. It is a figure for demonstrating the comparison of the synchronization time of the configuration of the configuration synchronization system which concerns on 1st Embodiment, and the synchronization time of the configuration of the configuration synchronization system which concerns on 2nd Embodiment. It is a general view (at the time of a failure) of the configuration synchronization system which concerns on the modification of 2nd Embodiment of this invention. It is a functional block diagram of the NE management apparatus which comprises the config synchronous system which concerns on the modification of 2nd Embodiment of this invention.

[Summary of Invention]
The present invention realizes a configuration synchronization system capable of performing configuration synchronization with respect to the NE N + m configuration. Specifically, the NE management device (EMS: Element Management System) plays a role as an order input system that inputs a command (SO) for rewriting the configuration to the NE. The present invention proposes how to hold a service order, and how to configure a working NE that was held at the time of switching, and how to put a service order that has already been put into a spare NE.

In the first embodiment, a system (configuration backup system) for backing up the configuration of the current NE every time the NE management apparatus inputs a service order will be described.
In the second embodiment, a method in which the NE management apparatus has a switching configuration in which information for identifying the spare NE is set (a switching configuration management method) will be described.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Each figure is only schematically shown so that the present invention can be fully understood. Therefore, the present invention is not limited to the illustrated example. In addition, in each figure, about the same component or the same component, the same code | symbol is attached | subjected and those overlapping description is abbreviate | omitted.

[First Embodiment]
Hereinafter, the configuration of the configuration synchronization system 1 according to the first embodiment will be described with reference to FIG. FIG. 1 is a configuration diagram of a configuration synchronization system 1 according to the first embodiment.

<< Configuration of Config Synchronization System According to First Embodiment >>
The configuration synchronization system 1 includes a business upper operation system (upper OpS) 2, an NE management device (EMS) 3, and N (N is a positive integer of 2 or more) # 1 to #N working NEs 5 (here Then, from # 1 to # 3 working NE5 only and m (a positive integer satisfying N> m) # 1 to #m spare NE6 (here, only # 1 spare NE6 is displayed) And an N + m redundant network 4. Here, the number (#) for identifying the working NE 5 and the number (#) for identifying the standby NE 6 are independent of each other, and the spare NE 6 is independent of the number (#) of the working NE 5. Can be a spare for any working NE5. For example, the # 1 spare NE6 can be a spare for the # 1 working NE5, the # 2 working NE5, or the # 3 working NE5.

  Note that the configuration synchronization system 1 can be configured in a virtual configuration. In the virtualization configuration, for example, a control system function such as a Session Border Controller is deployed on a virtual network as a Virtual Network Function (VNF), and only a packet transfer function is deployed on an actual physical device. At this time, the service order (SO) of the high added service that requires the control system function is set in the VNF, and the service order (SO) of the normal service that can be realized by packet transfer is set in the physical device.

  Each working NE 5 has a configuration that is setting information for each service and each user (in FIG. 1, only the working NE 5 of # 1 is shown). In the following, the configuration indicating the setting information at the time of startup is particularly referred to as “base configuration (BC: Base Config)”, and the configuration indicating the setting information after the service order is input to the base configuration is referred to as “running configuration ( RC: Running Config) ”. Specifically, the base configuration is information of only device information (such as the IP address of the device itself) and is information in a state where the service order is not reflected. On the other hand, the running config is information in a state where the service order is reflected in the base config.

  In the upper OpS2, service application information from the user is registered by the operator. In the present invention, various service forms are assumed, and the service forms applicable to the present invention are not limited to specific services. For example, a mass service (telephone service or Internet service) may be opened to a carrier network, or a specific communication service such as a VPN service may be realized. Here, a case where there is an application for a new contract for a specific communication service between a PC at the base A and a PC at the base B by a certain user and the information is registered in the upper OpS 2 will be described as an example. The host OpS 2 transmits a service order (SO) for realizing the registered service to the NE management apparatus 3. Here, the service order (SO) includes, for example, service information (VPN, PCC, etc.), order information (new contract, cancellation), user information, and the like.

  The NE management device 3 analyzes and sorts the service order received from the host OpS 2 and inputs (transmits) the service order as a command to the active NE 5 related to the applied service. Here, a service order (SO) is input to the working NEs # 1 to # 3 existing between the PC at the base A and the PC at the base B. The working NEs # 1 to # 3 to which the service order is entered rewrites the configuration held by itself based on the service order. As a result, a specific communication service (bold solid line in FIG. 1) between the PC at the base A and the PC at the base B is realized.

  The NE management device 3 acquires the running configuration (RC) after the SO is input from the active NE 5 that has input the SO each time the SO is input to the active NE 5, and the backup 31 of the acquired running configuration is stored in the storage unit. To store. Here, the backup 31 of the running configuration (RC) of the working NE 5 # 1 to # 3 to which SO is input is stored.

  Further, the NE management device 3 converts the backup 31 of the running configuration (RC) of the failed working NE 5 to the spare NE 6 when a certain working NE 5 fails, and the running configuration 61 converted to the spare NE 6 is converted to the running NE 61. Insert into the spare NE6. FIG. 2 shows a case where # 2 working NE5 fails. In this case, the backup configuration 31 (RC) backup of # 2 working NE5 is converted to # 1 spare NE6, The running configuration (RC) 61 of the # 1 spare NE 6 is input (configuration synchronization processing).

  Hereinafter, the configuration synchronization processing performed by the NE management apparatus 3 described so far will be described in detail with reference to FIG. In FIG. 3, functions other than the configuration synchronization processing (for example, functions related to SO input processing, etc.) are the same as those in the related art, and are not shown in the drawing and will not be described.

  The active RC acquisition unit 32 shown in FIG. 3 acquires the running configuration (RC) 51 after the SO is input from the active RC transmission unit 52 of the active NE 5 where the SO is input, and stores the backup 31 of the acquired running configuration 51 in the storage unit. Store. The communication method between the working RC acquisition unit 32 and the working RC transmission unit 52 is not particularly limited, and an existing protocol (for example, FTP) may be used or a new protocol may be used. As a result, the latest running configuration 51 that is the current setting of the working NEs # 1 to #N is stored in the storage unit of the NE management device 3. The active RC acquisition unit 32 may update the backup 31 of the running configuration 51 stored in the storage unit using the difference information.

  The failure detection unit 33 detects a failure in the network 4 (see FIG. 1). The method for detecting a failure is not particularly limited, and various methods can be used. Further, the working NE 5 itself may detect a failure by VRRP or the like and notify the failure detection unit 33 of the failure. When a failure is detected, the failure detection unit 33 notifies the terminal operated by the operator that the failure has been detected using a GUI (Graphical User Interface) or the like.

  When the RC conversion unit 34 switches from the working NE 5 to the standby NE 6 when a failure occurs, the RC conversion unit 34 matches the backup 31 of the running configuration (RC) 51 of the working NE 5 that is the switching source with the specifications of the standby NE 6 that is the switching destination. To convert. For example, the spare NE 6 for switching destination may be specified by, for example, a pair of switching source and switching destination being determined in advance, or an operator who has received a notification of the occurrence of a failure confirms the status of the network 4 It may be determined at this time.

The working RC input unit 35 inputs the running configuration 61 converted by the RC conversion unit 34 to the spare NE 6. The communication method of the working RC input unit 35 is not particularly limited, and an existing protocol (for example, FTP) may be used or a new protocol may be used. As a result, the standby NE 6 stores a running configuration 61 that is synchronized with the running configuration 51 of the failed active NE 5. And as shown in FIG. 2, the specific communication service (bold broken line in FIG. 2) between the PC of the base A and the PC of the base B is maintained.
This is the end of the description of the configuration of the configuration synchronization system 1 according to the first embodiment.

<< Business Flow Using Config Synchronization System According to First Embodiment >>
Hereinafter, the business flow using the configuration synchronization system 1 according to the first embodiment will be described with reference to FIG. 4 (see FIG. 3 as appropriate). Note that, as described above, the NE management device 3 stores the backup 31 of the running configuration 51 after the service order is input whenever the service order is input to the active NE 5.

  When a failure occurs in the working NE 5, the working NE 5 notifies the NE management device 3 that the failure has been detected (step S10). The failure detection unit 33 of the NE management device 3 displays the content of the failure notified to the terminal operated by the operator using the GUI or the like (step S20). Subsequently, the operator confirms the content of the failure, identifies (separates) the active NE 5 in which the failure has occurred, and designates the spare NE 6 to be switched to (step S30). Then, a switching preparation instruction specifying the switching destination spare NE 6 is transmitted from the terminal operated by the operator to the NE management apparatus 3 (step S40).

  The NE management device 3 that has received the switch preparation instruction performs a switch preparation process (step S50). Details of the switching preparation process are shown in FIG. The failure detection unit 33 of the NE management device 3 identifies the active NE 5 and the standby NE 6 that have detected the failure based on the switching preparation instruction transmitted from the operator (step S51). Then, the RC conversion unit 34 of the NE management device 3 converts the backup 31 of the running configuration (RC) 51 of the working NE 5 that has identified the failure into the specification of the standby NE 6 (step S52).

  Returning to FIG. 4, processing subsequent to step S <b> 52 will be described. The working RC input unit 35 of the NE management device 3 transmits a synchronization instruction to the standby NE 6 (step S60). This synchronization instruction includes the running configuration (RC) 61 converted into the specification of the spare NE 6 in step S52. The spare NE 6 stores the received running configuration (RC) 61 in its storage unit, thereby synchronizing the running configuration 51 held by the failed working NE 5 and the running configuration (RC) 61 stored in the spare NE 6. (Step S70).

  Subsequently, the spare NE 6 synchronizes the state (connection information such as the service status) with the current NE 5 (step S80). After completing the synchronization of the configuration and the state, the spare NE 6 transmits a synchronization completion notification indicating that the synchronization is completed to the NE management device 3 (step S90). The NE management device 3 that has received the synchronization completion notification transmits a switching preparation completion notification indicating that preparation for switching from the current NE 5 to the standby NE 6 has been completed to the terminal operated by the operator (step S100). The operator who has received the switch preparation completion notification transmits a switch instruction to the spare NE 6 existing in the remote place (step S110). Then, switching from the working NE 5 to the spare NE 6 is performed, and accordingly, the path is switched to the route through the spare NE 6. This completes the service takeover.

After that (possible at a later date), the operator arranges maintenance of the current NE 5 with respect to the local worker (step S120), and the local worker who has received the arrangement performs maintenance (step S130). Therefore, it is not necessary for the local worker to rush immediately when a failure occurs.
This is the end of the description of the business flow using the configuration synchronization system 1 according to the first embodiment.

  As described above, the configuration synchronization system 1 according to the first embodiment has the backup 31 of the latest running configuration (RC) 51 of the current NE 5 on the NE management device (EMS) 3 side, and is used as a spare at the time of switching. Convert to NE6 specifications. Therefore, it is possible to synchronize the configuration between the switching source active NE 5 and the switching destination spare NE 6. In addition, after reflecting the running configuration (RC) 61 in the spare NE 6, there is no need for past service order (SO) input processing, so the configuration synchronization time (switching time) can be shortened.

[Second Embodiment]
Hereinafter, the configuration of the configuration synchronization system 1A according to the second embodiment will be described with reference to FIG. FIG. 6 is a configuration diagram of a configuration synchronization system 1A according to the second embodiment.

<< Configuration of Configuration Synchronization System According to Second Embodiment >>
The configuration synchronization system 1A includes a business upper operation system (upper OpS) 2, an NE management device (EMS) 7, and N (N is a positive integer of 2 or more) # 1 to #N working NEs 5 (here Then, from # 1 to # 3 working NE5 only and m (a positive integer satisfying N> m) # 1 to #m spare NE6 (here, only # 1 spare NE6 is displayed) And an N + m redundant network 4. Here, the number (#) for identifying the working NE 5 and the number (#) for identifying the standby NE 6 are independent of each other, and the spare NE 6 is independent of the number (#) of the working NE 5. Can be a spare for any working NE5. For example, the # 1 spare NE6 can be a spare for the # 1 working NE5, the # 2 working NE5, or the # 3 working NE5.

  The NE management apparatus 7 according to the second embodiment has a base configuration (BC) 71 of the spare NE 6 in advance. In addition, the service order (SO) 72 that has been put into the working NEs 5 of # 1 to # 3 is held. The NE management device 7 sequentially puts the base configuration (BC) 71 of the spare NE 6 and the service order (SO) 72 that has already been put into the spare NE 6 when a certain working NE 5 fails. FIG. 7 shows a case where the # 2 working NE5 fails. In this case, the base configuration (BC) 71 of the # 1 spare NE6 and the service order (SO2) of the # 2 working NE5 are already entered. ) 72 are sequentially input to the spare NE 6 (config synchronization processing).

  Hereinafter, the configuration synchronization processing by the NE management apparatus 7 described so far will be described in detail with reference to FIG. In FIG. 8, functions other than the configuration synchronization processing (for example, functions related to SO input processing, etc.) are the same as those in the prior art, and are not shown in the drawing and will not be described.

  The backup BC management unit 73 shown in FIG. 8 stores the base configuration (BC) 71 of all the backup NEs 6 existing in the network 4 in the storage unit. As a result, the base configuration (BC) 71 of the spare NE 6 is always stored in the storage unit of the NE management device 7 even in a normal state. The spare BC management unit 73 may be a function that supports the creation of the base configuration (BC) 71 of the spare NE 6 by the operator.

  The input SO possession unit 74 stores the service order (SO) input to all active NEs 5 existing in the network 4 in the storage unit. Thereby, in the storage unit of the NE management device 7, the service order (SO) that has been input to the current NE 5 is added as needed.

  The failure detection unit 75 detects a failure in the network 4 (see FIG. 7). The method for detecting a failure is not particularly limited, and various methods can be used. Alternatively, the working NE 5 itself may detect a failure using VRRP or the like and notify the failure detection unit 75 of the failure. When a failure is detected, the failure detection unit 75 notifies the terminal operated by the operator that the failure has been detected using a GUI (Graphical User Interface) or the like.

  The spare BC input unit 76 inputs the base configuration (BC) 71 of the spare NE 6 stored in the storage unit to the spare NE 6 when switching from the current NE 5 to the spare NE 6 when a failure occurs. The communication method of the spare BC input unit 76 is not particularly limited, and an existing protocol (for example, FTP) may be used, or a new protocol may be used.

The already-inserted SO re-input unit 77 stores the service order (SO) 72 in which the faulty working NE 5 has been input after the backup configuration input unit 76 has input the base configuration (BC) 71 of the backup NE 6 into the backup NE 6. Insert into the spare NE6. The communication method of the injected SO re-input unit 77 is not particularly limited, and an existing protocol (for example, FTP) may be used, or a new protocol may be used. As a result, the standby NE 6 stores a running configuration 61 that is synchronized with the running configuration 51 of the failed active NE 5. And as shown in FIG. 7, the specific communication service (bold broken line in FIG. 7) between PC of the base A and PC of the base B is maintained.
This is the end of the description of the configuration of the configuration synchronization system 1A according to the second embodiment.

<< Business Flow Using Config Synchronization System According to Second Embodiment >>
A business flow using the configuration synchronization system 1A according to the second embodiment is shown in FIG. Differences from the business flow using the configuration synchronization system 1 according to the first embodiment shown in FIG. 4 are steps S50A to S70A. Below, the difference with the business flow of the configuration synchronization system 1 which concerns on 1st Embodiment among the business flows of the configuration synchronization system 1A which concerns on 2nd Embodiment is demonstrated (at any time, refer FIG. 8). Here, as described above, in the NE management device 7, the base configuration (BC) 71 of the spare NE 6 is stored in advance, and the service order (SO) 72 that has been put into the current NE 5 is added as needed. Has been.

  The details of the switching preparation process shown in step S50A are shown in FIG. The failure detection unit 75 of the NE management device 7 identifies the active NE 5 and the standby NE 6 that have detected the failure based on the switching preparation instruction transmitted from the operator (step S51A). Subsequently, the spare BC input unit 76 of the NE management device 7 specifies the base configuration (BC) 71 to be input to the spare NE 6 to be switched to (step S52A). In addition, the already-entered SO re-input unit 77 of the NE management device 7 specifies the service order (SO) that has been input to the working NE 5 that has specified the failure (step S53A).

Returning to FIG. 9, the continuation process of step S53A will be described. The backup BC input unit 76 and the input SO re-input unit 77 of the NE management device 7 transmit a synchronization instruction to the backup NE 6 (step S60A). This synchronization instruction includes the base configuration (BC) 71 specified in step S52A and the service order (SO) 72 already input specified in step 53A. The spare NE 6 stores the received base configuration (BC) 71 in its own storage unit and updates the received base configuration (BC) 71 based on the service order (SO), so that the faulty working NE 5 holds it. The running configuration 51 and the running configuration (RC) 61 stored in the spare NE 6 are synchronized (step S70A).
This is the end of the description of the business flow using the configuration synchronization system 1A according to the second embodiment.

  As described above, the configuration synchronization system 1A according to the second embodiment includes the base configuration (BC) 71 of the standby NE 6 and the service order (SO) 72 that has already been input to the current NE 5 on the NE management device (EMS) 7 side. The information is sequentially input to the spare NE 6 at the time of switching. Therefore, it is possible to synchronize the configuration between the switching source active NE 5 and the switching destination spare NE 6. Further, since the NE management device 7 manages the base configuration (BC) 71 of all the spare NEs 6 and the service order (SO) for each user, the accommodation of the users accommodated by the current NE 5 can be easily executed. Therefore, in addition to the failure of the working NE 5 (for example, when the resources of the working NE 5 are imminent), it is possible to replace a part of the users accommodated by the working NE 5 with the spare NE 6.

[Comparison of synchronization time of configuration synchronization system according to first embodiment and second embodiment]
Hereinafter, the configuration synchronization time of the configuration synchronization system 1 according to the first embodiment will be described in comparison with the configuration synchronization time of the configuration synchronization system 1A according to the second embodiment.

The RC conversion time is “t _convert ”, the BC input time is “t _BC ”, the config input time that is increased for each user of one service is “t _RC ”, the NE startup time by BC is “t _bootBC ”, and one service 1 _Assuming that the startup time of the NE that increases for each user is “t _bootRC ”, the SO setting time of one user for one service is “t _SO ”, the number of services is “n”, and the number of accommodated users of the current NE is “x” The configuration synchronization time T _{1 of the first} embodiment and the configuration synchronization time T ₂ of the second embodiment are as shown in the following equations (1) and (2).
T ₁ = t _convert + t _BC + n * x * t _RC + t _{boot BC} + n * x * t _bootRC (1)

T ₂ = t _BC + t _bootBC + n * x * t _SO (2)

On the other hand, in the case of a virtual configuration, since only the SO set in the physical device needs to be synchronized, assuming that the number of normal services is “m”, the configuration synchronization time T ₃ of the first embodiment and the second embodiment The synchronization time T ₄ of the configuration shown in (3) is expressed by the following equations (3) and (4).
T ₃ = t _convert + t _BC + m * x * t _RC + t _{boot BC} + m * x * t _bootRC (3)

T ₄ = t _BC + t _bootBC + m * x * t _SO (4)

FIG. 11 shows the synchronization times T ₁ , T ₂ , T ₃ , and T ₄ of the configurations of the equations (1) to (4) with respect to the number of users. Referring to FIG. 11, in the non-virtualized configuration, the switching configuration management method according to the second embodiment can be applied if the number of users is small. However, the NE that accommodates tens of thousands of users that require redundancy. In this case, it can be seen that the configuration backup method according to the first embodiment is appropriate. In the virtual configuration (in the case of “n = 3” and “m = 1”), the configuration backup method according to the first embodiment and the configuration management method for switching according to the second embodiment are non-virtualized configurations. Compared to the case, the result that the synchronization time of the configuration is equal or less is obtained.

[Modification]
As mentioned above, although embodiment of this invention was described, this invention is not limited to this, It can implement in the range which does not change the meaning of a claim. The modification of embodiment is shown below.

  In the configuration synchronization system 1A according to the second embodiment, as shown in FIG. 7, when a certain working NE 5 fails, the NE management device 7 uses the base configuration (BC) 71 of the spare NE 6 and the service order ( SO) 72 was sequentially added to the spare NE 6, and the running configuration 61 was created by the spare NE 6. However, the running configuration (RC) of the spare NE 6 may be created in advance from the time before the failure occurs or on the NE management device 7 side when the failure occurs, and the created running configuration (RC) may be input to the spare NE 6.

  In the case where the running configuration (RC) of the spare NE 6 is created in advance before the failure occurs, for example, the running configuration (RC) of each spare NE 6 (for example, when the working NE 5 of # 1 becomes the switching source) The running configuration (RC) of the spare NE 6 and the running NE (# 2) when the # 2 working NE 5 is the switching source, and the spare NE 6 when the # 3 working NE 5 is the switching source. The running configuration (RC)) is stored in the storage unit in advance. That is, in the network 4 having the N + m configuration, the running configuration (RC) for the spare NE 6 having a pattern corresponding to “the number N of the current NEs × the number m of the spare NEs” is stored in the storage unit. Until a failure occurs, each time a service order (SO) is input from the upper OpS2, the service order (SO) is input to the current NE 5 and the corresponding number (#) stored in the storage unit is reserved. Update the running configuration (RC) of NE6. Corresponding to the corresponding number (#) of the faulty working NE5 and the corresponding number (#) of the spare NE6 to be switched from among the N × m running configurations (RC) stored in the storage unit when a failure occurs The attached running configuration (RC) is input to the spare NE 6. Thereby, the time for failure recovery can be advanced.

  When creating the running configuration (RC) of the spare NE 6 when a failure occurs, for example, as shown in FIG. 12, the base configuration 71 of the spare NE 6 and the service order (SO) 72 that has been put in are held. . Then, the running configuration (RC) 71B of the spare NE 6 is created by updating the base configuration (BC) 71 of the spare NE 6 using the service order (SO) 72 that has been input when a failure occurs, and the running configuration thus created (RC) 71B is put into the spare NE6. FIG. 13 shows a functional configuration diagram of the NE management apparatus 7 in this case. In FIG. 13, functions other than the configuration synchronization processing (for example, functions related to SO input processing, etc.) are the same as those in the related art, and are not shown in the drawing and will not be described.

  When switching from the current NE 5 to the spare NE 6 in the event of a failure, the spare RC creating unit 78 shown in FIG. 13 uses the service order (SO) 72 that has already been put in place the base configuration (BC) 71 of the spare NE 6. The running configuration (RC) 71B of the spare NE 6 is created by updating.

  The spare RC input unit 79 inputs the running configuration (RC) 71B of the spare NE 6 created by the spare RC creating unit 78 to the spare NE 6. The communication method of the standby RC input unit 79 is not particularly limited, and an existing protocol (for example, FTP) may be used, or a new protocol may be used. As a result, the standby NE 6 stores a running configuration 61 that is synchronized with the running configuration 51 of the failed active NE 5. Then, as shown in FIG. 12, a specific communication service (bold broken line in FIG. 12) between the PC at the base A and the PC at the base B is maintained.

1,1A, 1B Config synchronization system 2 Upper OpS
3,7 NE management device 4 Network 5 Current NE
6 NE for spare
32 Current RC acquisition unit 33 Failure detection unit 34 RC conversion unit 35 Current RC input unit 52 Current RC transmission unit 73 Preliminary BC management unit 74 Inputted SO holding unit 75 Failure detection unit 76 Preliminary BC input unit 77 Inputted SO re- Input section 78 Preliminary RC creation section 79 Preliminary RC input section

Claims (2)

The network is communicably connected to a working NE (Network Element) constituting the network and a spare NE used as a spare for the working NE, and a service order is input to the working NE and from the working NE to the spare NE. A NE management device for switching between
A storage unit that stores a backup base config (BC) in which information for identifying the backup NE is set;
An input SO possession unit that stores in the storage unit a service order that has been input to the current NE;
A spare BC loading unit for loading the spare base configuration to the spare NE when switching from the current NE to the spare NE;
An already-entered SO re-injection unit for injecting the already-injected service order to the spare NE;
NE management apparatus characterized by the above. It is communicably connected to a working NE that constitutes a network and a spare NE used as a spare for the working NE. A service order is input to the working NE and a switch from the working NE to the spare NE is performed. A configuration synchronization method for an NE management device,
A storage unit for storing a spare base config in which information for identifying the spare NE is set;
The service order that has been put into the working NE is stored in the storage unit,
At the time of switching from the current NE to the spare NE, the spare base config is thrown into the spare NE, and the previously placed service order is thrown into the spare NE.
Config synchronization method characterized by the above.

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