KR102312500B1 - System and method for mobility management - Google Patents

Abstract

A mobility management system according to an embodiment of the present invention includes a plurality of smart mobile edges that create one or more virtual entities for providing a service to a user terminal, and the user terminal is located in the area of one smart mobile edge of another smart mobile edge. and a mobility service manager that provides the service by applying one or more of a session connection management control, a scaling control, a migration control, and a chaining control to the virtual entity when moving to an area.

Description

Mobility management system and method

The present invention relates to a mobility management technology, and more particularly, to a technology for actively and optimally providing mobility management of a user terminal.

In the future network environment where smart mobile terminals and M2M solutions are expected to rapidly increase, mobile traffic is also expected to increase significantly. In addition, the wireless network needs to evolve into an integrated platform to provide various services through interworking with various types of IoT devices such as wireless sensors, which are expected to increase exponentially in the future.

To this end, the mobile edge and the core network need to be able to provide a programmable infrastructure framework to provide personalized services and high-quality services in the network closest to the user through virtualization technology. . Therefore, the future mobile network requires a network infrastructure that can be reconfigured to create new value for operators and service providers through proximity and context-based services, which are oriented to the nearest service to users, and fast and active mobility management.

An object of the present invention is to provide a mobility management system that provides a programmable infrastructure framework through virtualization technology.

According to an aspect of the present invention, a plurality of smart mobile edges for creating one or more virtual entities for providing a service to a user terminal; and when the user terminal moves from an area of one smart mobile edge to an area of another smart mobile edge, one or more of session connection management control, scaling control, migration control, and chaining control is applied to the virtual entity to provide the service. A mobility management system comprising a; mobility service manager to provide is provided.

The scaling control may be a method of generating an extended virtual entity extending the virtual entity of the one smart mobile edge on the other smart mobile edge, and providing the service through the extended virtual entity.

The migration control may be a method of moving the virtual entity of the one smart mobile edge to the other mobile edge and providing the service through the moved mobile edge.

The chaining control may be a method of providing the service through some virtual entities of the one smart mobile edge and some virtual entities of the other smart mobile edge.

The session connection management control may be a method of maintaining a user session by controlling a connection function and connection management corresponding to the virtual entity of the one smart mobile edge.

According to another aspect of the present invention, there is provided a method for a mobility management system to manage mobility of a user terminal, the method comprising: creating, by a smart mobile edge, one or more virtual entities for providing a service to the user terminal; and when the mobility service manager moves the user terminal from the area of one smart mobile edge to the area of another smart mobile edge, one or more of session connection management control, scaling control, migration control, and chaining control is applied to the virtual entity. to provide the service; is provided a mobility management method comprising a.

The scaling control may be a method of generating an extended virtual entity extending the virtual entity of the one smart mobile edge on the other smart mobile edge, and providing the service through the extended virtual entity.

The migration control may be a method of moving the virtual entity of the one smart mobile edge to the other mobile edge and providing the service through the moved mobile edge.

The chaining control may be a method of providing the service through some virtual entities of the one smart mobile edge and some virtual entities of the other smart mobile edge.

The session connection management control may be a method of maintaining a user session by controlling a connection function and connection management corresponding to the virtual entity of the one smart mobile edge.

As described above, according to an embodiment of the present invention, a personalized service and a high-quality service can be provided in a network closest to the user.

1 is a diagram illustrating a mobility management system according to an embodiment of the present invention.
2 is a diagram illustrating a mobility management process provided by a mobility service manager of a mobility management system according to an embodiment of the present invention.
3 is a diagram illustrating a form in which a virtual entity of a mobility management system according to an embodiment of the present invention is disposed.
4 is a diagram illustrating a process in which the mobility management system according to an embodiment of the present invention performs mobility management through session connection control.
5 is a diagram illustrating a process in which the mobility management system performs scaling control according to an embodiment of the present invention.
6 is a diagram illustrating a process in which the mobility management system performs migration control according to an embodiment of the present invention.
7 is a diagram illustrating a process in which the mobility management system performs chaining control according to an embodiment of the present invention.
8 is a diagram illustrating a process in which the mobility management system according to an embodiment of the present invention performs mobility management through a method of mixing a plurality of control methods.
9 is a diagram illustrating a computer system in which a mobility service manager and a smart mobile edge included in the mobility management system according to an embodiment of the present invention are implemented.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail through the detailed description. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

In addition, in this specification, when it is said that one component "transmits" a signal to another component, the one component may be directly connected to the other component to transmit a signal, but there is a particularly opposite description. Unless otherwise noted, it should be understood that a signal may be transmitted through another component in the middle.

1 is a diagram illustrating a mobility management system according to an embodiment of the present invention.

1 , the mobility management system according to an embodiment of the present invention includes a smart mobile edge (110, SME: Smart Mobile Edge), a mobility service manager (140, MSM: Mobility Service Manager) and a management function (MF: Management). Functions, 150).

The smart mobile edge 110 includes a reconfigurable network infrastructure 120 (RNI) and a mobility driving function 130 (MEF: Mobility Enabling Functions).

The reconfigurable network infrastructure 120 is formed through virtual entities operating on a reconfigurable environment (RE) 122 . The reconfiguration environment 122 is an integrated environment composed of software and hardware, and refers to a virtualization environment in which the virtual entity 124 operates through virtualization technology. The virtual entity 124 is a unit of virtualization component driven by software in the reconfigurable network infrastructure 120 and is divided into four types (controller virtual entity, device virtual entity, function virtual entity, and application virtual entity), and one A network can be defined and reconfigured within a reconfigurable infrastructure through a group including the above virtual entities.

A controller virtual entity (CVE) refers to a controller-type virtual entity 124 for chaining of the virtual entity 124 , connection management of a user session, or mobility management. A virtualized software defined networking (SDN) controller may be an example, and a location management control function or an anchoring control function for mobility management also falls under the category of the controller virtual entity 124 , and proxy control or Brokering control may also be the role of the controller virtual entity 124 .

A Device Virtual Entity (DVE) is in the form of a virtualized virtual entity 124 of a user device, and may manage the virtualized user device through profile management.

A Function Virtual Entity (FVE) is a type of virtual entity classified as a function for an application service or network connection, such as a traditional middle box type network function or a cache function for a content service. A function of accelerating screen transmission through virtualization of a user's screen may also belong to the category of the functional virtual entity 124 .

An application virtual entity (AVE) is a virtualized form of a component for an application service, and refers to a virtualized entity for a component of an application area such as a web server, a content server, or a DB server.

The mobility driving function 130 is optimized through the virtual entity 124 using user-related information, information about the virtual entity 124 and information related to virtual resources of management functions (MF) 150 . Provides a mobility control mechanism. The mobility driving function 130 may perform mobility management through an interface with the mobility service manager 140 responsible for end-to-end mobility management. The mobility driving function 130 may be largely divided into four functions (session connection control function, scaling control function, migration control function, chaining control function).

The Session Connectivity Control Function (SCCF) is one of the traditional mobility management methods, in which the user session connection management function manages mobility by changing the connection topology. That is, when the user's terminal moves, the mobility driving function 130 controls the connection function with the virtual entity related to the user's terminal and the connection management between the related virtual entities, so that the user session even when the user's terminal moves. can keep

A scaling control function (VSCF: VE Scaling Control Function) corresponds to a case of a driving function in which a scaling technique is used for optimal mobility management of a user. Certain virtual entities related to a user's service may need to be expanded or reduced to ensure the mobility of the service when necessary. That is, the scaling control function is a function that supports the mobility of the user terminal through scaling of the corresponding virtual entity through operations such as scale in/out or scale up/down of the virtual entity based on the situation.

A migration control function (VMCF: VE Migration Control Function) is a function that supports mobility management of a user terminal through movement management of a virtual entity. A virtual entity may be moved to different hosts or nodes within one SME, or may be moved remotely to an SM in another geographically separated region. That is, the migration control function may be used when providing a user environment in which a virtual entity follows the user terminal when the user moves by moving a specific virtual entity based on the situation to manage the mobility of the user terminal.

In addition, the mobility driving function 130 is a chaining control function (VE Chaining Control Function) that efficiently chains virtual entities so that the user's packet flow passes through a plurality of virtual entities and arrives at the last destination can be reconstructed. . The chaining technique functions to link virtual entities of multiple sites to achieve the same effect as operating at one site in mobility management.

Accordingly, the mobility driving function 130 operates as a basic operation for optimizing mobility management, and the four mobility driving functions 130 may be combined and used as an optimization technique. For example, when the user terminal moves, the mobility driving function 130 of the user session connection control (SCCF) and migration control (VMCF) functions may be combined to perform optimized mobility management.

The mobility service manager 140 performs integrated orchestration and mobility management between the smart mobile edges 120 . When mobility management control between the aforementioned smart mobile edges 120 is required or when mobility management is required for policy, the mobility service manager 140 transmits the mobility management policy to each smart mobile edge 120, and each virtual entity Place the virtual entity through the profile of The mobility service manager 140 includes a profile manager (PM), an integrated orchestrator (GO: Global Orchestrator), and a mobility manager (MM: Mobility Manager).

The profile manager 142 stores the specification of each virtual entity for the virtual entity to be installed and driven in the smart mobile edge 120, detailed information about characteristics or functions, and information necessary for or generated during operation of the virtual entity. Manage the included profile. In this case, when an attribute is changed during mobility management, the virtual entity may transmit a message notifying that the attribute is changed to the profile manager 142 .

The integrated orchestrator 144 maps resources and virtual entities corresponding to the entire smart mobile edge 120 to each smart mobile edge 120 , and performs overall deployment and lifecycle management. The integration orchestrator 144 performs network control for the virtual entity allocation of resources or a connection between the virtual entities.

The mobility manager 146 transmits the mobility control management policy to the smart mobile edge 120 through a policy decision for end-to-end mobility management, and collects information necessary to create the mobility control management policy.

The management function (MF: Management Functions, 150) performs lifecycle management of the entire service and resources corresponding to each virtual entity within the distributed smart mobile edge. In particular, the management function extracts and manages information for state management, failure management, and performance management of the resource. In addition, the corresponding information is information necessary for optimizing mobility management. The management function collects the corresponding information through the interface with the smart mobile edge or mobility service manager, and management control can perform it.

The application may include an interface with an application service of the mobility service manager, an application service provider, or an infrastructure provider such as OSS/BSS. Applications may include engineering interfaces such as big data analytics. Each interface can collect and feed back information required for configuration and orchestration of policy elements or virtual entities required by the mobility service manager.

For example, the control API means a control interface between the mobility service manager and the smart mobile edge. The control API transmits control information for managing mobility between the mobility manager of the mobility service manager and the mobility driving function of the smart mobile edge. The mobility service manager and the smart mobile edge may each perform triggering first. The integrated orchestrator and smart mobile edge can exchange information for lifecycle management of virtual entities through the control API.

An application AIP (Application API) is an interface between an application service and a mobility service manager, and may be used to exchange service management information including information related to a policy and a requirement for mobility management of the application service.

The integrated management API (Global Management API) is a management interface of resources related to an end-to-end service between a mobility service manager and a management function. The unified management API can be used in the mobility service manager to transmit information for lifecycle management of virtual entities deployed and operated at the smart mobile edge distributed in the network.

The local management API (Local Management API) is used to perform lifecycle management of the resource of the virtual entity through the management function without going through the mobility service manager among the smart mobile edge. In particular, in order to perform the function of the mobility driving function, an interface with the management function is required, and the management function or the smart mobile edge may perform the triggering first.

A user API (User API) is an interface between a user terminal and a mobility service manager. In general, it can be said that the application is included in the user terminal, but the user API may be an interface used to make a direct request for a mobility management policy or control management for a service used by the user himself/herself.

2 is a diagram illustrating a mobility management process provided by a mobility service manager of a mobility management system according to an embodiment of the present invention.

Referring to FIG. 2 , in step 210 , the mobility service manager 140 collects movement information indicating that the location of the user terminal moves.

In step 220, the mobility service manager 140 according to the movement of the user terminal, the mobility service manager 140 before moving the smart mobile edge 120 corresponding to the user terminal and the virtual entities and virtual entities related to the smart mobile edge 120 Collects entity profile information.

In step 230, the mobility service manager 140 creates a mobility management scenario through analysis of the mobility information and the profile information of the virtual entity. The mobility management scenario is information representing a procedure for optimizing mobility management between the smart mobile edge 120 before movement and the smart mobile edge 120 after movement of the user terminal. For example, the mobility service manager 140 performs a migration scenario or a chaining after scaling scenario through analysis of information on virtual entities required between the smart mobile edge 120 before moving and the smart mobile edge 120 after moving, etc. can create Mobility management scenarios can be created by integrally analyzing current network status information, resource status or capacity for smart mobile edge, service policy information, and the like. That is, when the application service requires low latency, the mobility service manager 140 may create a mobility management scenario that provides mobility through migration so that the service can be provided at the nearest smart mobile edge 120 . In addition, in the case of a service that requires a network function rather than a low latency, the mobility service manager 140 can create a mobility management scenario that utilizes the virtual entity of the smart mobile edge 120 before moving through chaining according to the network situation. . In addition, when the capacity of the resource is sufficient but the virtual entity providing the function is insufficient, the mobility service manager 140 supports the access of the user terminal through scaling or provides an existing connection to the user through the connection between smart mobile edges. Mobility management scenarios can be created that persist as-is.

In step 240, the mobility service manager 140 determines a set of operations constituting the mobility management scenario and the order of each operation. The operation may be composed of four unit operations performed by the mobility driving function 130 of the smart mobile edge, and an execution command may be performed according to each operation. For example, when the operation is a command to control session connection, the mobility service manager 140 collects connection information between the smart mobile edge 120 for session connection, and after moving the smart mobile edge 120 and before moving A session connection request may be transmitted to the hahak smart mobile edge 120 to maintain the user session as it is through the connection between the smart mobile edges. In addition, when performing scaling, migration, and chaining, the mobility service manager 140 collects information on the smart mobile edge 120 or virtual entity related according to the operation, and collects the parameters determined in the mobility management scenario and operation of the corresponding virtual entities. can be used to perform each operation. In addition, in the case of an operation on the same smart mobile edge and in the case of an operation performed between different smart mobile edges, the mobility service manager 140 may cause the operations to be performed in the same order.

In step 250, the mobility service manager 140 checks whether there is an operation to be performed next among the operations constituting the mobility management scenario.

If there is no operation to be performed next in step 250 , the mobility service manager 140 ends the mobility management process.

If there is an operation to be performed next in step 250 , the mobility service manager 140 checks the type of operation to be performed next in step 260 .

When the type of operation to be performed next in step 260 is a session connection control operation, in step 262 the mobility service manager 140 collects session connection information.

In step 264, the mobility service manager 140 transmits a session connection request to the smart mobile edge.

If the type of operation to be performed next in step 260 is a scaling control operation, in step 266 the mobility service manager 140 collects scaling virtual entity information.

In step 268, the mobility service manager 140 requests scaling to the smart mobile edge according to the scaling virtual entity information.

If the type of operation to be performed next in step 260 is a migration control operation, in step 270 the mobility service manager 140 collects migration virtual entity information.

In step 272, the mobility service manager 140 requests migration to the smart mobile edge according to the migration virtual entity information.

In step 260, when the type of operation to be performed next is a chaining control operation, in step 274, the mobility service manager 140 collects chaining virtual entity information.

In step 276, the mobility service manager 140 transmits a chaining request to the smart mobile edge according to the chaining virtual entity information.

At this time, after steps 264, 268, 272 and 276 described above, the mobility service manager 140 repeats the process from step 250 .

Accordingly, the mobility service manager 140 may provide an active mobility management service by performing session connection control, scaling control, migration control, and chaining control according to operations.

3 is a diagram illustrating a form in which a virtual entity of a mobility management system according to an embodiment of the present invention is disposed.

Referring to FIG. 3 , the mobility management system may include one or more distributed smart mobile edges (SME-1 to SME-5). The mobility management system may create one or more virtual entities on each smart mobile edge. The mobility service manager 140 identifies a virtual entity required to provide a service through a management function, and places the identified virtual entity in an optimal location. In this case, the virtual entity may be created and managed using attribute information registered through the profile manager 142 as a virtual entity requiring an application.

One smart mobile edge may include one or more virtual entities, and smart mobile edges related to one service may be configured and connected as a virtual network as needed. In addition, the mobility management system may configure a management channel with a plurality of smart mobile edges to dynamically manage mobility.

4 is a diagram illustrating a process in which the mobility management system according to an embodiment of the present invention performs mobility management through session connection control.

Referring to FIG. 4 , when the user terminal 50 moves from SME-1 to SME-2, in order to maintain the user session, there is a need for a method of classifying the user session in the infrastructure to ensure the mobility of the session as it is. For example, when the virtual entity is the controller virtual entity, the mobility service manager 140 of the mobility management system may perform session connection control of the user terminal 50 while maintaining the function of the controller virtual entity. In this case, the reconfiguration of the virtual entity itself does not occur, and the session connection between the mobility service manager 140 and the smart mobile edge 120 using the interworking between the reconfigurable network infrastructures constituting the virtual entity and the connection control of the external network. Control may be performed.

5 is a diagram illustrating a process in which the mobility management system performs scaling control according to an embodiment of the present invention.

Referring to FIG. 5 , when the user terminal 50 moves from SME-1 to SME-2, even if the same virtual entity as the virtual entity operating in SME-1 exists in SME-2, it is more difficult due to performance or capacity issues. In the above SME-2, it may be determined that a normal service of the virtual entity is difficult. In this case, the mobility management system may extend and use the virtual entity of SME-2 in addition to using the virtual entity of SME-1. That is, the mobility management system may provide a service by connecting the newly created virtual entity of SME-2 and the user terminal by scaling out the virtual entity of SME-1.

6 is a diagram illustrating a process in which the mobility management system performs migration control according to an embodiment of the present invention.

Referring to FIG. 6 , the mobility management system moves the virtual entity used in SME-1 to SME-2 when the user terminal 50 moves from SME-1 to SME-2, and then moves the virtual entity and the user terminal. Mobility can be managed through migration control that provides services by connecting 50. Preferably, migration control can be used primarily when a personal device is virtualized, such as a device virtual entity. Alternatively, if there is a disaster or a change in resources, migration control may be performed.

7 is a diagram illustrating a process in which the mobility management system performs chaining control according to an embodiment of the present invention.

Referring to FIG. 7 , when the user terminal 50 moves from SME-1 to SME-2, the mobility management system uses some virtual entities of SME-1 as it is and chaining control using some of the virtual entities of SME-2. service can be provided through That is, the mobility management system may provide a service by simultaneously connecting two virtual entities of SME-1 and virtual entities of SME-2.

In this case, the mobility management system may use a mixture of the four control methods for mobility management described above with reference to FIGS. 4 to 7 . Hereinafter, a process of mixing and using a plurality of control methods will be described with reference to FIG. 8 .

8 is a diagram illustrating a process in which the mobility management system according to an embodiment of the present invention performs mobility management through a method of mixing a plurality of control methods.

Referring to FIG. 8 , when the user terminal 50 moves from SME-1 to SME-2, the mobility management system moves one virtual entity on SME-1 to SME-2 and determines the access path of the user terminal. A new connection path can be configured by chaining two virtual entities of SME-1 and the virtual entity moved to SME-2. That is, the mobility management system may perform mobility management for the user terminal 50 through a method in which migration control and chaining control are mixed.

The mobility service manager 140 and the smart mobile edge 120 included in the mobility management system according to an embodiment of the present invention described above may be implemented as a computer system.

9 is a diagram illustrating a computer system in which a mobility service manager and a smart mobile edge included in the mobility management system according to an embodiment of the present invention are implemented.

An embodiment according to the present invention may be implemented in a computer system, for example, in a computer-readable recording medium. As shown in FIG. 9 , the computer system 900 includes at least one or more of a processor 910 , a memory 920 , a storage 930 , a user interface input unit 940 , and a user interface output unit 950 . It may include elements, which may communicate with each other via bus 960 . In addition, computer system 900 may also include a network interface 970 for connecting to a network. The processor 910 may be a CPU or a semiconductor device that executes processing instructions stored in the memory 920 and/or the storage 930 . The memory 920 and the storage 930 may include various types of volatile/nonvolatile storage media. For example, the memory may include ROM 924 and RAM 925 .

So far, the present invention has been looked at focusing on the embodiments thereof. Many embodiments other than the above-described embodiments are within the scope of the claims of the present invention. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

Claims (10)

a plurality of smart mobile edges for creating one or more virtual entities for providing services to user terminals; and
When the user terminal moves from an area of one smart mobile edge to an area of another smart mobile edge, one or more control functions of session connection management control, scaling control, migration control, and chaining control are applied to the virtual entity to provide the service Mobility Services Manager to provide;
including,
The mobility service manager collects profile information of virtual entities related to smart mobile edges, creates a mobility management scenario through analysis of the profile information, and determines a set of operations constituting the mobility management scenario and the order of each operation do,
When a plurality of control functions are required for at least one specific virtual entity to provide the service, the mobility service manager performs a plurality of the session connection management control, scaling control, migration control, and chaining control according to the type of operation. Mobility management system for sequentially applying to the at least one specific virtual entity by giving an order to the plurality of control functions, including
According to claim 1,
The scaling control is a method of generating an extended virtual entity extending the virtual entity of the one smart mobile edge on the other smart mobile edge, and providing the service through the extended virtual entity.
According to claim 1,
The migration control is a method of moving the virtual entity of one smart mobile edge to the other smart mobile edge, and providing the service through the moved virtual entity.
According to claim 1,
The chaining control is a method of providing the service through some virtual entities of the one smart mobile edge and some virtual entities of the other smart mobile edge.
According to claim 1,
The session connection management control is a method of maintaining a user session by controlling a connection function and connection management corresponding to the virtual entity of the one smart mobile edge.
A method for a mobility management system to manage mobility of a user terminal, the method comprising:
creating, by the smart mobile edge, one or more virtual entities for providing services to the user terminal; and
When the mobility service manager moves the user terminal from the area of one smart mobile edge to the area of another smart mobile edge, the mobility service manager controls at least one of session connection management control, scaling control, migration control, and chaining control for the virtual entity. providing the service by applying;
including,
In the step of providing the service,
The mobility service manager collects profile information of virtual entities related to smart mobile edges, creates a mobility management scenario through analysis of the profile information, and determines a set of operations constituting the mobility management scenario and the order of each operation later,
When a plurality of control functions are required for at least one specific virtual entity to provide the service, the session connection management control, scaling control, migration control, and chaining in the order given by the mobility service manager according to the type of operation A mobility management method for sequentially applying the plurality of control functions including a plurality of controls to the at least one specific virtual entity.
7. The method of claim 6,
The scaling control is a method of generating an extended virtual entity extending the virtual entity of the one smart mobile edge on the other smart mobile edge, and providing the service through the extended virtual entity.
7. The method of claim 6,
The migration control is a method of moving the virtual entity of the one smart mobile edge to the other smart mobile edge, and providing the service through the moved virtual entity.
7. The method of claim 6,
The chaining control is a method of providing the service through some virtual entities of the one smart mobile edge and some virtual entities of the other smart mobile edge.
7. The method of claim 6,
The session connection management control is a method of maintaining a user session by controlling a connection function and connection management corresponding to the virtual entity of the one smart mobile edge.

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