KR102182644B1 - Apparatus for network management providing scalability and decentralization and method thereof - Google Patents

Abstract

Disclosed is an apparatus and method for flexibly extending a scale-out method and operating a network management system in a segregated manner according to the configuration distribution and characteristics of network elements to be managed for each network domain and service purpose. According to an aspect, an apparatus for managing at least one sub-network management system that is disposed in each of at least one or more network domains and manages network elements constituting each network domain is at least one type capable of independently executing a network management function. A generator for generating the above network management module; A determination unit that determines the type and number of network management modules to be distributed to the at least one sub-network management system; And a distribution unit for distributing network management modules corresponding to the type and number determined by the determination unit to the at least one sub-network management system.

Description

Apparatus for network management providing scalability and decentralization and method thereof

The present invention relates to a network management technology, and more specifically, to an apparatus and method for extending a network management system in a scale-out manner and operating in a separate manner.

Network implementation technology is also important to realize a hyper-connected society that aims to connect all things, but a network management system (NMS:Network) that can efficiently manage all the things connected to the network and the communication connection. Management System) is also important. Since objects connected to the network and the amount of communication accordingly increase explosively, it is difficult to cope with the structure of the current scale-up type network management system, so it is necessary to switch to a scale-out type structure.

In addition, as the emergence of new services that require ultra short latency support such as self-driving cars, drone remote/autonomous flight, and telemedicine is imminent, network functions are shifted from core to edge (closer to users). It is a trend toward forward deployment. Accordingly, it is necessary to follow a decentralized structure so that local network elements in each main domain can be independently managed in each local domain rather than overall management in a central network management system. At this time, since the characteristics and sizes of the network elements constituting each domain are different, the characteristics and sizes of the network management system in charge of the domain must be adjusted differently.

In a hyper-connected society, the weight of wireless communication increases and the number of network connections of moving objects increases very much. At this time, the number of management target network elements in each local domain is also very flexible. Therefore, the structure of the network management system in charge of each domain should also have a flexible structure that can reflect this flexibility.

As a method of solving the explosive network element quantity and liquidity in an ultra-connected environment based on the structure and technology of a conventional network management system, there are a method of adding hardware and a method of reinforcing a software system.

As a method of expanding a hardware system, a representative method is to increase computing power by adding a memory or CPU, but a method of satisfying the performance requirements by reinforcing one system in terms of hardware has physical/technical limitations.

The conventional network management system implementation technology that reinforces a software system is a scale-up method. A representative patent is "Design for scalable network management systems (US Patent 6,968,371)", which aims to build a highly scalable network management system and targets large-scale voice/data networks. It is a method of grouping and managing network elements to be managed into groups of a specific size, and one sub-system of the network management system is arranged for each group. The subsystem consists of network management unit functions and unit processes, and only one network management function and process instance is created and included in one subsystem. When the number of network elements to be managed increases beyond a preset size, the network elements beyond that are grouped into separate groups, and a new subsystem is created and allocated for management of this new group.

The problem of the hardware expansion method is something that can be easily recognized by an engineer with basic knowledge in this field, so no further explanation is required. Problems in the case of trying to solve the reinforcement of the software system with the prior art (especially the US patent technology described above) can be described as follows.

First, the inventors of the US patent mentioned above also define their ideas in a scale-up method. Single network management to manage a new network environment that is constantly increasing and changing with high connectivity, ultra-low latency, and ultra-complexity characteristics. It is generally known that the scale-up method of the system can improve the performance up to an initial certain level, but after a certain point, no further performance improvement is made or the performance decreases.

In addition, in a situation where network functions are deployed near the user terminal so that various new services that require ultra-low latency can be released, managing these network functions in a centralized way is to accurately monitor and manage the required ultra-low delay characteristics. It is likely to lead to unmanageable results.

Network elements to be managed (eg, switches, routers, gateways, servers, links, etc.) belonging to a management group having a specific size have different characteristics as each network device. Looking at the distribution of management target network elements included by group, each group will be composed of different network elements. However, according to the prior art, the configuration of the sub-system of the network management system that will manage each group is the same (since the existing sub-system is copied when a new group is created), computing resources are inefficiently allocated. It will lead to the result.

US registered patent US 6,968,371 (2005.11.22)

The present invention was created under the recognition of the prior art as described above, and the network management system can be flexibly extended in a scale-out manner according to the configuration distribution and characteristics of network elements to be managed for each network domain, and service purpose It is an object of the present invention to provide an apparatus and a method to enable it.

According to an aspect, an apparatus for managing at least one sub-network management system that is disposed in each of at least one or more network domains and manages network elements constituting each network domain is at least one type capable of independently executing a network management function. A generator for generating the above network management module; A determination unit that determines the type and number of network management modules to be distributed to the at least one sub-network management system; And a distribution unit for distributing network management modules corresponding to the type and number determined by the determination unit to the at least one sub-network management system.

The determiner may determine the type and number of network management modules to be distributed based on characteristics of network domains and network elements managed by the at least one sub-network management system.

The determination unit may determine the type and number of network management modules to be additionally distributed whenever a new network element is added to a specific network domain.

The determination unit may determine the type and number of additional network management modules to be distributed when a new network element is added to the specific network domain and the management capability of the sub-network management system managing the specific network domain is exceeded.

The management module may include at least one of a linkage module, an alarm module, an analysis module, and a collection module.

The at least one sub-network management system is a Network Function Virtualization (NFV) system, and the generator may generate the at least one network management module in the form of a Virtualized Network Function (VNF).

The at least one or more network domains may be any one of an access network domain, a core network domain, and an edge network domain connecting the access network domain and the core network domain.

According to another aspect, a method of managing at least one sub-network management system that manages network elements constituting each network domain by being deployed in each of at least one or more network domains in a central network management system is to independently execute a network management function. Generating at least one or more types of network management modules; Determining the type and number of network management modules to be distributed to the at least one sub-network management system; And distributing a network management module corresponding to the determined type and number to the at least one sub-network management system.

In the determining step, the type and number of network management modules to be distributed may be determined based on characteristics of network domains managed by the at least one sub-network management system and characteristics of network elements.

In the determining step, each time a new network element is added to a specific network domain, the type and number of network management modules to be additionally distributed may be determined.

In the determining step, when a new network element is added to the specific network domain and the management capability of the sub-network management system for managing the specific network domain is exceeded, the type and number of network management modules to be additionally distributed may be determined. .

The management module may include at least one of a linkage module, an alarm module, an analysis module, and a collection module.

The at least one sub-network management system is a network function virtualization (NFV) system, and the generating step may generate the at least one network management module in the form of a virtualized network function (VNF).

The at least one or more network domains may be any one of an access network domain, a core network domain, and an edge network domain connecting the access network domain and the core network domain.

According to an aspect of the present invention, by managing each network domain in a separate type rather than a centralized management type, it is possible to quickly manage network elements operating in each network domain, thereby providing ultra-low latency services. have.

In addition, according to another aspect of the present invention, by creating at least one type of network management module capable of independently executing network management and putting it into the subnetwork management system of each network domain adaptively according to the characteristics of each network domain, It is possible to prevent the waste of computing resources and network resources used for management.

In addition, according to another aspect of the present invention, since all of the sub-network management systems deployed in each network domain are composed of a common network management module, they can be grouped together and operated organically and provide a single view of the entire network. Can provide.

The following drawings attached to the present specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention described later, the present invention is the matter described in such drawings. It is limited to and should not be interpreted.
The following drawings attached to the present specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention described later, the present invention is the matter described in such drawings. It is limited to and should not be interpreted.
1 is a schematic configuration diagram of a system according to an embodiment of the present invention.
2 is a schematic internal configuration diagram of the network management system of FIG. 1.
3 is an exemplary diagram of a network management module distributed by the central network management system of FIG. 1 to a sub network management system.
4 is a schematic internal configuration diagram of the central network management system of FIG. 1 managing a network management module.
5 is a schematic flowchart of a network management method according to an embodiment of the present invention.
6 is an exemplary view comparing the conventional system and the system of FIG. 1.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to a conventional or dictionary meaning, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical spirit of the present invention, and thus various alternatives that can be substituted for them at the time of application It should be understood that there may be equivalents and variations.

1 is a schematic configuration diagram of a system 1 according to an embodiment of the present invention.

The system 1 according to an embodiment of the present invention corresponds to network domains 121 to 123 that provide communication services and each network domains 121 to 123, so that network elements in each network domain 121 to 123 are A managed sub network management system (Sub Network Management System, hereinafter referred to as'sub NMS') 111 to 113 and a central network management system that manages the sub network management systems 111 to 113 (Core Network Management System, Hereinafter referred to as'central NMS') 100. Network management means that the communication service provider manages the status of functions and operations of various network elements constituting the network domain that provides communication services to subscribers. Here, the network element means a switch, router, gateway, server, link, etc.

The network domains 121 to 123 are composed of respective network elements for communication services to provide communication services. The network domains 121 to 123 are classified according to the function and layer of the network, and include an access network domain 121, an edge network domain 122, and a core network domain 123. The access NMS 111, the edge NMS 112, and the core NMS 113 corresponding to the sub NMS are allocated to each of the network domains 121 to 123. Here, the network domains 121 to 123 have unique characteristics. The above characteristics are network service requirements, such as hyper-connection, ultra-low latency, network function, layer, configuration and characteristics of network elements, and network size.

The access network domain 121 is a domain that provides a network access function to an end terminal of a subscriber, and is managed by a corresponding access NMS 111. The access network domain 121 includes network elements such as an AP (Access Point) to which an end terminal is connected, a base station, and a gateway device. The access network domain 121 provides network access functions such as 5G access, Wi-Fi access, and wired access to an end terminal.

The edge network domain 122 relays signals between at least one access network domain 121 and the core network domain 123, and is managed by a corresponding edge NMS 112. The edge network domain 122 includes network elements such as a router device, a switch device, a gateway device, and a server that relay signals between the access network and the core network.

The core network domain 123 provides a communication service to an end terminal of a subscriber accessing at least one edge network domain 121 and is managed by a corresponding core NMS 113. The core network domain 123 is composed of unique communication devices according to the generation or type of communication service. For example, the core network domain 123 includes network elements such as Mobility Management Entity (MME), Home Subscriber Server (HSS), Serving-Gateway (S-GW), and Packet Data Network-Gateway (P-GW). Include.

As described above, the sub NMSs 111 to 113 include the access NMS 111, the edge NMS 112 and the core NMS 113. The sub-NMS (111 to 113) is provided with a predetermined number of at least one or more network management modules 101 for managing the assigned domains (121 to 123) from the central NMS (100), the provided network management module Install and run (101). At this time, the sub NMSs 111 to 113 are built with a Network Function Virtualization (NFV) architecture, and the network management module 101 is implemented in the form of a Virtual Network Function (VNF) operating on a Virtual Machine (VM) in this NFV architecture. I can.

The central NMS 100 generates the network management module 101 in consideration of the characteristics of each domain 121 to 123 and the characteristics of network elements constituting each domain 121 to 123, and determines the type and number And, it distributes and manages the network management modules 101 of the determined type and number to the sub-NMSs 111 to 113. The types of the network management module 101 will be described later with reference to FIG. 3. The central NMS 100 can also be constructed with an NFV (Network Function Virtualization) architecture like the sub NMSs 111 to 113, and as described above, the central NMS 100 uses the network management module 101 as a VM (Vritual Machine). ) Can be created in the form of a Virtual Network Function (VNF) that operates on the sub-NMS (111 to 113).

FIG. 2 is a schematic internal configuration diagram of an NFV architecture constituting the network management systems 100 and 111 to 113 of FIG. 1. The NFV architecture largely includes a group 101 of virtual network function (VNF) instances, an NFV infrastructure 230, and a Management and Orchestration (MANO) 210.

MANO 210 provides physical and software resource management, delivery, and VNF management functions. Specifically, MANO 210 manages and controls NFV infrastructure 230 resources, that is, computing hardware 231, storage hardware 232, and network hardware 233, and manages and controls overall network orchestration in a multi-NFV infrastructure environment. It performs the function to manage. In addition, the MANO 210 performs life cycle management for the VNF instance 101. In addition, MANO 210 manages VM (Virtual Machine) resource management, router (or switch), firewall policy, and the like.

The MANO 210 may include an orchestrator, one or more VNF managers, and one or more virtualized infrastructure managers.

MANO 210 is configured to perform supervision and management of VNF instances 101 and NFV infrastructure 230. The orchestrator may be implemented in the NFV infrastructure 230 and virtual resources in the NFV infrastructure 230. In addition, the orchestrator can realize networks such as L2 and L3 VPN services on the NFV infrastructure 230. The orchestrator implements a request related to a resource, transmits configuration information to the VNF manager, and communicates with one or more VNF managers to collect status information of the VNF instance 101. In addition, the orchestrator may communicate with the virtualized infrastructure manager to preserve and exchange resource allocation and/or virtualized hardware resource configuration and state information. The VNF manager manages one or more VNF instances.

The VNF manager performs various management functions such as instantiating, updating, quering, scaling, and/or terminating the VNF instance 101. The virtualized infrastructure manager includes computing hardware 231, storage hardware 232, network hardware 233, virtual computing 234, and virtual storage. 235 and a virtual network 236 perform management functions used to control and manage the interaction of the VNF instance 101. For example, the virtualized infrastructure manager performs resource management functions such as operations such as managing and allocating infrastructure resources and collecting NFV infrastructure failure information. The VNF manager and the virtualized infrastructure manager communicate with each other for resource allocation requests and exchange virtualized hardware resource configuration and status information.

The NFV infrastructure 230 includes a hardware component, a software component, or a combination thereof for building a virtual environment (eg, a VM) and deploying, managing, and executing the VNF instance 101. That is, a hardware resource and a virtualization layer are used to provide virtualized resources such as VMs and other types of virtual containers for the VNF instance 101. Hardware resources include computing hardware 231, storage hardware 232 and network hardware 233. The computing hardware 231 may be commercial off-the-shelf (COTS) hardware and/or custom hardware that processes resources and is used for computing. The storage hardware 232 provides storage capacity that is provided within the network or resides within the storage hardware (ie, local memory located within the server). The network hardware 233 may be a switch, a router, and/or other network equipment that performs a switching function that may be interconnected through a wireless or wired link. The network hardware 233 may span several domains, and may include a plurality of networks interconnected through one or more transport networks.

The virtualization layer in the NFV infrastructure 230 abstracts hardware resources, separates the VNF instance 101 from the physical network layer located below it, and provides a virtualized resource to the VNF instance 101. . As shown in FIG. 2, virtualized resources include virtual computing 234, virtual storage 235 and virtual network 236. The virtual computing 234 and virtual storage 235 may be provided to the VNF instance 101 in the form of a hypervisor, VM or other virtual container. For example, one or more VNF instances 101 may be deployed in the VM. The virtualization layer abstracts the network hardware 233 to form a virtual network. The virtual network includes a virtual switch that provides connectivity between the VMs hosting the VNF instance 101 and/or other virtual containers. The abstraction of hardware resources may be implemented using various technologies including virtual LAN, VPLS, VxLAN, and Network Virtualization using Generic Routing Encapsulation (NVGRE), but is not limited thereto. In addition, the transmission network in the network hardware 233 may be virtualized using a central control plane and a separate forwarding plane, for example, a Software Defined Network (SDN).

In the NFV architecture of FIG. 2, the VNF instance 101 is the network management module 101 described with reference to FIG. 1. Therefore, the MANO 210 of the central NMS 100 uses the NFV infrastructure 230 to comprehensively analyze the characteristics of each domain 121 to 123 and the network elements constituting each domain 121 to 123. By analyzing and determining the type and number of network management modules 101 to be distributed to the sub-NMSs 111-113 that manage each domain (121-123), the network management module 101 of the determined type and number is created. It can be distributed as a sub-NMS (111-113) and can also manage the life cycle. Meanwhile, the MANO 210 of each sub NMS 111 to 113 installs and executes the network management module 101, which is a VNF instance distributed from the central NMS 100, on the VM, and also controls the central NMS 100. Accordingly, the life cycle of the network management module 101 can be managed and deleted.

3 is an exemplary diagram of a network management module 101 distributed by the central NMS 100 of FIG. 1 to sub-NMSs 111 to 113. The central NMS 100 and the sub NMS 111 to 113 provided by the present invention are systems that manage various network elements built to provide communication services to subscribers. The core concept proposed by the present invention is to decompose the functions for network management into the smallest scale that can operate independently, and unitize the decomposed functions into modules, and then the characteristics of each network domain (121 to 123) (e.g., Service purpose) and the network management module required as the sub-NMS (111-113) that manages each network domain (121-123) according to the characteristics (configuration distribution, personality, etc.) of network elements in each network domain (121-123) 101) is to be put in the required amount. In this way, the network management module 101 decomposed and united into a minimum scale is composed of several types.

As shown in FIG. 3, the network management module 101 may be configured in four types, such as "interlock", "alarm", "analysis", and "collection". However, it is not necessarily limited thereto, and may be configured in various types according to functions for network management. The interworking module executes a management function for the network operation in which the network element to be managed is linked with an external system. The alarm module executes a management function that outputs alarms for failures, performance and security threats occurring in network elements. The analysis module performs a management function that extracts and analyzes events generated from network elements. The collection module executes a management function that collects performance and failure information from network elements.

The type and quantity of the network management modules 101 to be distributed to the sub NMSs 111 to 113 of the present invention are the characteristics of the network domains 121 to 123 to be managed and the network elements constituting each network domains 121 to 123 It is determined according to the characteristics of their size and purpose. For example, when a telecommunications company establishes a new network for subscribers, network management to be put into the sub-MMS (111-113) depending on whether the target area is an area where factories or companies are concentrated, or a residential area such as an apartment complex Different types and numbers of modules 101 are organized. Since stable operation of the company/factory area is important, it is required to put enough “analysis” module to accurately analyze the network situation and “alarm” module to generate an alarm in a timely manner when a problem occurs. On the other hand, in the case of a residential area (especially an apartment area), a communication company needs to carefully collect the network usage information of users of individual households, so it is required to put a lot of "collection" modules.

Here, the network management modules 101 of each of the sub-NMSs 111 to 113 form one network management system and independently operate network management for each corresponding network domain 121 to 123. That is, due to the segregation, the small sub-NMS 111 manages the network only for the small access network domain 121, and the large sub-NMS 113 manages the network only for the large core network domain 123.

4 is a schematic internal configuration diagram of the central NMS 100 of FIG. 1 managing the network management module 101. Referring to FIG. 4, the central NMS 100 includes a generation unit 410, a determination unit 420 and a distribution unit 430.

The generation unit 410 generates various types of network management modules 101 such as an interworking module, an alarm module, an analysis module, and a collection module that can independently execute a network management function divided into a minimum unit.

The determination unit 420 determines the type and number of network management modules 101 to be distributed to each of the sub-NMSs 111 to 113 in consideration of the characteristics of each network domain requiring management. Here, the determination unit 420 determines the type and number of network management modules 101 to be additionally distributed whenever a new network element is added to a specific network domain.

When a new network element is added and the management capability of the sub NMS 111-113 is exceeded accordingly, the type of network management module 101 to be distributed for network management of the added network element And the number can be determined. In addition, when changes such as the addition of network elements as well as reduction of network elements occur, the decision unit 42 is a network management module to be additionally distributed for network management of the changed network elements in a specific network domain (121-123). It is possible to determine the type and number of (101) and to delete the network management module (101) that has already been distributed but unnecessary. To this end, the determination unit 420 may receive information of reduced network elements in each network domain 121 to 123 from the network management module 110 for collection distributed to each sub NMS 111 to 113. .

The distribution unit 430 distributes the network management modules 101 of the type and number determined by the determination unit 420 to the sub NMSs 111 to 113 of the corresponding network domain. By the distribution, the sub NMSs 111 to 113 receive, install and execute the network management module 101. If the deletion of the network management module 101 of the sub-NMS 111-113 is determined, the distribution unit 430 may transmit a deletion command of the network management module 101 to the corresponding sub-NMS 111-113. have. Here, the deletion command may be life cycle information.

In the present invention, since the sub-NMSs 111-113 arranged in each network domain 121-123 are composed of network management modules 101 distributed from the central NMS 100, they are grouped as a whole and organically integrated into one NMS. It can be managed as, and thus, the central NMS 100 can provide a single view of the entire network.

5 is a schematic flowchart of a network management method according to an embodiment of the present invention.

The central NMS 100 decomposes the network management function into functions of the smallest size that can be independently executed, and creates the network management module 101 of the disassembled function. For reference, as an embodiment, four types of network management modules 101 of interworking, alerting, analysis, and collection are created. Network domains 121 to 123 composed of various network elements can be established. Accordingly, sub-NMSs 111 to 113 for managing network elements belonging to the corresponding network domains 121 to 123 may be constructed. That is, sub-NMSs 111-113, which are physical systems for managing the network domains 121-123, may be constructed. At this time, the network management module 101 is not distributed to the sub NMSs 111 to 113. When the new network domains 121 to 123 and the sub NMSs 111 to 113 for managing the new network domains 121 to 123 are constructed, the central NMS 100 By combining the characteristics and the characteristics of network elements belonging to the network domains (121-123), the type and number of network management modules 101 to be distributed to the sub-NMS (111-113) are determined, and the corresponding network domains (121-123) are determined. ) To be deployed to the sub-NMS (111 to 113) built in (S501).

Thereafter, the network management module 101 distributed and introduced to the sub NMSs 111 to 113 is installed and executed to execute a network management function to manage the target network domains 121 to 123 (S503).

During network management, network elements may be newly added to the network domains 121 to 123 for any reason (S505). The central NMS 100 can receive information on the added network elements from the administrator, or information on network elements added from the sub-NMS 111-113 that manages the network domains 121-123 to which the network elements are added. Can receive. At this time, the network management module 101 for collection at the time of initial construction is essential to the sub NMS 111 to 113, and the network management module 101 for the collection collects information on newly added network elements, 100).

By adding network elements, the central NMS 100 analyzes the characteristics of network elements added to the network domains 121 to 123 to be managed and the characteristics of the corresponding network domains 121 to 123, and the required network management module The type and quantity of (101) are determined, and the network management module 101 of the determined type and quantity is distributed to the corresponding sub-NMSs 111 to 113 and injected (S507, S509). At this time, when new network elements are added, the central NMS 100 can additionally distribute the network management module 101 only when the management capability of the sub-NMS 111 to 113 is exceeded by the added network elements. .

6 is an exemplary view comparing the conventional system and the system of FIG. 1. For convenience of explanation, a case where the communication network is expanded due to the formation of a new city is taken as an example. In the conventional system for network management, as shown in Fig. 6 (a), ① by the formation of a new city, ② when the communication network is expanded, ③ a sub of the existing network management system that manages the area for management of the expanded network. The system is expanded by the scale-up method, and ④ The sub-system expanded by the scale-up method manages the newly expanded communication network. According to the scale-up method, the subsystem of the existing network management system that manages the area is memory, CPU, and Hardware resources such as DB are added to manage the communication network. On the other hand, in the system of an embodiment, as shown in (b) of FIG. 6, when ① a new city is formed, ② when a communication network is expanded, ③ sub NMSs (111 to 113) that manage the area for management of the expanded network It is expanded in a scale-out method. That is, the central NMS 100 determines the type and quantity of the network management module 101 according to the characteristics of the network elements of the expanded network and the characteristics of the expanded network, and selects the network management module 101 of the determined type and quantity. It is distributed as a sub-NMS (111~113) that manages the expanded communication network. ⑤ Sub NMS (111 to 113) manage the newly expanded communication network by executing the network management module 101 of the determined type and quantity.

Therefore, the system of an embodiment of the present invention quickly manages the network elements operating in each network domain (121-123) by managing each network domain (121-123) in a separate type rather than a centralized management type. As it can be performed, it can provide ultra-low latency service. In addition, by creating at least one type of network management module 101 that can independently execute network management, adaptively manages sub-networks of each network domain (121-123) according to the characteristics of each network domain (121-123). By putting them into the systems 111-113, it is possible to prevent the waste of computing resources and network resources used for network management. In addition, since the sub-network management systems 111-113 arranged in each network domain 121-123 are all composed of the network management module 101 distributed from the central NMS 100, not their own modules, It can be grouped together to operate organically and provides a single view of the entire network.

Although the present invention has been described by limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and claims to be described below by those of ordinary skill in the art to which the present invention pertains. Of course, various modifications and variations are possible within the uniform range of the range.

100: central NMS 101: network management module
111~113: sub NMS 121~123: network domain

Claims (14)

In the apparatus for managing at least one subnetwork management system that is disposed in each of at least one or more network domains to manage network elements including at least one of switches, routers, gateways, servers, and links constituting each network domain,
A generator for generating at least one type of network management module capable of independently executing a network management function;
A determination unit that determines the type and number of network management modules to be distributed to the at least one sub-network management system; And
And a distribution unit for distributing network management modules corresponding to the type and number determined by the determination unit to the at least one sub-network management system. The method of claim 1,
The determination unit,
And determining the type and number of network management modules to be distributed based on characteristics of network domains and network elements managed by the at least one sub-network management system. The method of claim 2,
The determination unit,
An apparatus, characterized in that, whenever a new network element is added to a specific network domain, the type and number of network management modules to be additionally distributed are determined. The method of claim 3,
The determination unit,
When a new network element is added to the specific network domain and the management capability of the sub-network management system for managing the specific network domain is exceeded, the type and number of network management modules to be additionally distributed are determined. The method of claim 1,
The management module,
An apparatus comprising at least one of a linkage module, an alarm module, an analysis module, and a collection module. The method of claim 1,
The at least one or more sub-network management systems,
It is a Network Function Virtualization (NFV) system,
The generation unit,
An apparatus, characterized in that generating the at least one or more network management modules in the form of a Virtualized Network Function (VNF). The method of claim 1,
The at least one or more network domains,
An apparatus, characterized in that it is any one of an access network domain, a core network domain, and an edge network domain connecting the access network domain and the core network domain. In the central network management system, at least one sub-network management system is deployed in each of at least one or more network domains to manage network elements including at least one of switches, routers, gateways, servers, and links constituting each network domain. In the way,
Generating at least one type of network management module capable of independently executing a network management function;
Determining the type and number of network management modules to be distributed to the at least one sub-network management system; And
And distributing a network management module corresponding to the determined type and number to the at least one sub-network management system. The method of claim 8,
The determining step,
And determining the type and number of network management modules to be distributed based on characteristics of network domains and network elements managed by the at least one sub-network management system. The method of claim 9,
The determining step,
A method, characterized in that whenever a new network element is added to a specific network domain, the type and number of additional network management modules to be distributed are determined. The method of claim 10,
The determining step,
When a new network element is added to the specific network domain and the management capability of the sub-network management system managing the specific network domain is exceeded, the type and number of additional network management modules to be distributed are determined. The method of claim 8,
The management module,
A method comprising at least one of an interworking module, an alarm module, an analysis module, and a collection module. The method of claim 8,
The at least one or more sub-network management systems,
It is a Network Function Virtualization (NFV) system,
The generating step,
A method comprising generating the at least one or more network management modules in the form of a Virtualized Network Function (VNF). The method of claim 8,
The at least one or more network domains,
An access network domain, a core network domain, and an edge network domain connecting the access network domain and the core network domain.

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