KR20190049507A - Network system, network apparatus and control method thereof, control method of network node - Google Patents

Abstract

The present invention proposes a method for reducing delay of signaling process for a terminal through reducing signaling between network nodes (NFs) when processing signaling for the terminal by realizing a control function moving technique capable of moving/mounting a control function mounted on an NF to another NF.

Description

TECHNICAL FIELD [0001] The present invention relates to a network system, a network device applied thereto, and an operation of the network device, a method of operating a network node,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control function movement technique capable of moving / mounting a control function mounted on a network node to another network node.

5G communication system is an advanced mobile broadband (EMBB) / massively machine type communications (MMTC) / ultra-reliable and large scale communication (MMLC) system, which accommodates as many terminals as possible based on limited radio resources. low latency communications, high reliability and low latency communications).

In particular, the URLLC service, which is supported by the 5G communication system, is considered to be very important in terms of the user experience. Various research and development are under way to support this.

5G defines a network structure for end-to-end support of terminal, base station (access), core and server.

Specifically, in the 5G, unlike the existing LTE (4G), a network structure is defined in which a control signaling function area and a data transmission / reception function area (User Plane) are classified.

In this case, the network node of the control plane in the 5G includes an access and mobility function (AMF) for controlling access to the wireless section of the terminal, an authentication service function (AUSF) for controlling an authentication procedure for authenticating whether the subscriber is a legitimate subscriber, A policy control function (PCF) for managing / controlling policies such as subscriber information and subscription service information per subscriber, billing, an SMF (Session Management Function) for managing / controlling a session for using data services for each terminal, It is defined as Network Repository Function (NRF), Network Exposure Function (NEF), Network Slice Selection Function (NSSF), User Data Management (UDM) and AF (Application Function) that manage and control information about network nodes. can do.

Each network node in this Control Plane is called a Network Function (hereinafter referred to as NF) that performs its own control function and performs its control function.

In 5G, the network node of the User Plane is defined as a UPF (User Plane Function) that transmits and receives data between a terminal and a data network (for example, the Internet) through a session with the terminal based on the SMF control .

In the signaling process for the UE, a large number of signaling is exchanged between the NFs for performing control functions and signaling processes performed by the corresponding NFs for each network node, i.e., each NF.

Therefore, in the 5G, due to a large number of signaling between each physically independent NF, there is a delay as much as the latency for every signaling between NFs during signaling processing for the terminal.

However, at present, in 5G, there is not proposed a method for eliminating a considerable delay caused in the signaling process for the UE due to a large number of signaling between each physically independent NF.

In the present invention, a method for reducing signaling processing delay for a terminal by reducing signaling between NFs occurring in the signaling processing for the terminal is proposed.

An object of the present invention is to realize a new method of reducing signaling processing delay for a UE by reducing signaling between NFs occurring in a signaling process for the UE.

According to an embodiment of the present invention, a network system comprises: a plurality of network nodes which are equipped with at least one control function; And a control node for allowing a specific control function of a specific network node, which is required to separate a control function among the plurality of network nodes, to be mounted on another selected one of the plurality of network nodes.

Specifically, when the control node requests control function separation to the specific network node and a context information response for a specific control function detachable from the specific network node is returned, the control node transmits the context information It is possible to select another network node capable of implementing the specific control function.

Specifically, the control node may cause the specific control function and the context information separated from the specific network node to be transferred to the other network node, so that the specific control function may be loaded on the other network node.

According to an embodiment of the present invention, a network device includes: a control function unit having at least one control function; A separator for separating a specific control function separable from the at least one control function based on user context information to separate the specific control function; And a control unit for providing at least one of the separated specific control function and the user context information to the control node so that the specific control function can be mounted on another network device selected on the basis of the user context information by the control node .

Specifically, the other network device may be any one of a plurality of network devices, a network device in a position closer to the terminal than the network device in a signaling procedure with the terminal.

Specifically, the control unit may provide the specific control function and the user context information to the other network device, or allow copying from the other network device to the specific control function and the user context information, And the specific control function can be loaded on another network device.

Specifically, the control function unit can update the information related to the specific control function among the at least one control function according to update information received at any time or on a predetermined period basis from the specific control function of the other network device have.

According to an embodiment of the present invention, a network device includes: a control function unit having at least one control function; And a control unit for acquiring a specific control function separated from other network devices based on the user context information and mounting the specific control function of the other network device on the network device; Each control function of the control function unit transmits a specific signaling according to the user context information to be transmitted to a specific control function of the other network device during signaling to the terminal to the specific control function of the control unit, The specific signaling may be processed.

Specifically, the specific control function may be performed during a predetermined holding period after the mounting, or until a time when a resource shortage occurs to perform the specific control function other than the resource for performing the control function of the control function unit, Can be mounted.

Specifically, each of the control functions of the control function unit may be configured such that, when a resource shortage occurs to perform the specific control function other than the resource for performing the control function of the control function unit, .

According to an embodiment of the present invention, an operation method of a network device includes dividing a specific control function separable based on user context information among at least one control function installed in the network device, A separating step of separating; And a function of providing at least one of the separated specific control function and the user context information to the control node so that the specific control function can be mounted on another network device selected on the basis of the user context information by the control node And a control step.

Specifically, the control node provides the specific control function and the user context information to the other network device, or allows copying from the other network device to the specific control function and the user context information So that the specific control function is loaded on another network device.

Specifically, the method may further include updating management information related to the specific control function among the at least one control function, in accordance with update information received at any time or on a predetermined period basis from the specific control function of the other network device have.

According to an embodiment of the present invention, there is provided a method of operating a network device, comprising: installing at least one control function; Acquiring a specific control function separated on the basis of the user context information from another network device and mounting the specific control function of the other network device on the network device; Wherein the at least one control function transmits specific signaling according to the user context information to be transmitted to a specific control function of the other network device during signaling to the terminal to the specific control function of the control part, And a signaling step for causing the specific signaling to be processed.

Specifically, the specific control function is a function of, during a predetermined holding time after mounting, or until a time when a resource shortage occurs to perform the specific control function other than the resource for performing the control function of the control function unit, Can be mounted on.

Specifically, when at least one control function generates a resource shortage to perform the specific control function other than the resource for performing the control function of the control function unit, the at least one control function may perform the specific signaling as a specific control function of the other network device And a step of transmitting the data.

According to an embodiment of the present invention, a method of operating a network node supporting a specific service includes: loading at least one control function for operation of the network node; Processing the signaling for signaling of the terminal through the at least one control function and between the control functions; And storing the result information associated with the signaling process in a specific data store associated with the particular service and not being retained in the control function each time the signaling is processed in each control function.

Specifically, the result information may include status information of a control function that has performed the signaling process, and user context information of at least one of the terminal and the signaling service.

In particular, the control function comprises at least one component having a software form for performing the control function, the at least one component comprising a signaling input, a signaling process, It can have the function of signaling output.

Therefore, according to the embodiments of the present invention, a control function movement technique capable of moving / loading a control function mounted on the network node NF to / from another NF is realized, and signaling between each NF It is expected that the signaling processing delay for the terminal can be reduced.

Thus, according to the embodiments of the present invention, the effect of efficiently supporting the request / performance of the service type supported by 5G is derived.

1 is an exemplary diagram illustrating a 5G network system.
2 is an exemplary diagram illustrating signaling between NFs in a signaling process of a UE in a 5G network system.
3 is an exemplary diagram illustrating a network system according to an embodiment of the present invention.
4 and 5 are block diagrams showing a configuration of a network device (network node) according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating signaling between NFs in a signaling process of a UE in a network system according to an embodiment of the present invention. Referring to FIG.
7 is a flowchart illustrating an operation method of a network device (network node) according to an embodiment of the present invention.
8 is a flowchart illustrating an operation method of a network node according to an exemplary embodiment of the present invention.
9 is a conceptual diagram showing a structure (environment) of a micro NF according to an embodiment of the present invention.
FIG. 10 is an exemplary diagram illustrating information about micro NF according to an exemplary embodiment of the present invention. Referring to FIG.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

The present invention considers the 5G communication system introduced in the future.

5G communication system is an advanced mobile broadband (EMBB) / massively machine type communications (MMTC) / ultra-reliable and large scale communication (MMLC) system, which accommodates as many terminals as possible based on limited radio resources. low latency communications, high reliability and low latency communications).

In particular, the URLLC service, which is supported by the 5G communication system, is considered to be very important in terms of the user experience. Various research and development are under way to support this.

5G defines a network structure for end-to-end support of terminal, base station (access), core and server.

Specifically, in the 5G, unlike the existing LTE (4G), a network structure is defined in which a control signaling function area and a data transmission / reception function area (User Plane) are classified.

In this case, the network node of the control plane in the 5G includes an access and mobility function (AMF) for controlling access to the wireless section of the terminal, an authentication service function (AUSF) for controlling an authentication procedure for authenticating whether the subscriber is a legitimate subscriber, A policy control function (PCF) for managing / controlling policies such as subscriber information and subscription service information per subscriber, billing, an SMF (Session Management Function) for managing / controlling a session for using data services for each terminal, It is defined as Network Repository Function (NRF), Network Exposure Function (NEF), Network Slice Selection Function (NSSF), User Data Management (UDM) and AF (Application Function) that manage and control information about network nodes. can do.

Each network node (also referred to as a control node) of this Control Plane is called a Network Function (hereinafter referred to as NF) that performs its own control function and performs its control function.

A network node (also referred to as a data node) of the User Plane in the 5G is a UPF (User) that transmits and receives data between a terminal and a data network (e.g., the Internet) through a session with the terminal based on control Plane Function).

Figure 1 shows a 5G network system.

In FIG. 1, AMF, AUSF, PCF, and NRF are shown as network nodes NF of Control Plane for the convenience of explanation, and UPF is shown as NF of User Plane.

5G, a large number of signaling messages are exchanged between NFs for performing control functions and signaling processes of corresponding NFs for each network node, that is, NFs, during the signaling process for the terminal 1. [

Particularly, a state of transiting the operation state of the terminal 1, for example, a state where the terminal 1 is connected to the core network (for example, an idle-to-active state), a state where the terminal 1 is switched to the idle state (For example, Active-to-Idle), a situation in which the UE 1 moves to another access node (e.g., a base station) May be large.

Therefore, in the 5G, there is a delay in the signaling process for the terminal 1 due to a large number of signaling between the physically independent NFs, i.e., AMF, AUSF, PCF, and the like.

Hereinafter, signaling between NFs in the signaling process for the terminal 1 will be briefly described in an Attach situation (e.g., idle-to-active) in which the terminal 1 accesses the core network with reference to FIG.

As shown in FIG. 2, the terminal 1 transmits a request message for accessing the core network to the AMF when a radio section is connected through signaling with an AMF through an access terminal, that is, the base station 10.

At this time, the message (signaling) transmitted / received between each NF including the request message transmitted by the terminal 1 to the AMF will suffice if it is a message defined in 5G. For convenience of explanation, I will refer to each message by its name.

That is, when the terminal 1 transmits an Attach Request message for accessing the core network to the AMF, the AMF transmits an authentication message requesting authentication of the terminal 1 to the AUSF that performs the control function of the authentication procedure, The AUSF sends a policy message requesting the policy for the terminal 1 to the PCF that performs the policy / management control function.

The PCF returns a response message to the AUSF in response to a policy such as subscription service information and billing for the terminal 1. The AUSF then performs an authentication procedure for the terminal 1 based on the returned policy, (E.g., authentication success) to AMF.

Accordingly, the AMF transmits an N / W information message requesting information (hereinafter, N / W information) about each network node NF related to the terminal 1 to the NRF, and receives a response message responding thereto , And transmits an Attach Complete message informing the terminal 1 of completion of connection to the core network.

After the Attach Complete message is received and the core network connection is completed, the terminal 1 can transmit and receive data to the data network (e.g., the Internet) through the NF of the User Plan, that is, the UPF.

Of course, the transmission / reception (signaling) between each NF, AMF, AUSF, PCF, and NRF described with reference to FIG. 2 may be an embodiment, and the order and kind of signaling may vary depending on the order and type defined in 5G .

As can be seen from the above description with reference to FIG. 2, in 5G, due to a large number of signaling between physically independent NFs, i.e., AMF, AUSF, PCF, etc., in signaling processing for terminal 1, There is a delay as much as the latency.

In addition, due to the delay of the signaling process, there is also a disadvantage that the service start time, which can transmit and receive the actual data in the terminal 1, is slow.

However, at present, in 5G, there is not proposed a method for eliminating a considerable delay caused in the signaling process for the UE due to a large number of signaling between each physically independent NF.

Accordingly, the present invention proposes a method for reducing the signaling processing delay (delay) for the UE by reducing signaling between NFs occurring in the signaling process for the UE.

Specifically, the present invention proposes a network system and a network device (network node) capable of implementing a proposed new scheme (hereinafter referred to as a control function movement technology).

Hereinafter, a network system according to an embodiment of the present invention will be described with reference to FIG.

Since the present invention takes 5G into consideration, the network system of the present invention may also be a 5G network system.

3, a network system according to an exemplary embodiment of the present invention includes a plurality of network nodes equipped with at least one control function, a status monitoring unit for monitoring statuses of the plurality of network nodes, And a control node (300) for causing a specific control function of a specific network node that requires separation of control functions among the nodes to be mounted on another selected one of the plurality of network nodes.

A plurality of network nodes denote network nodes of Control Plane and User Plane, that is, NFs in 5G, and FIG. 3 shows AMF, AUSF, PCF, and NRF for convenience of explanation.

The control node 300 may be a separate network node located in the core network or one of existing network nodes, for example NRF or NEF.

This control node 300 monitors the status of a plurality of network nodes, i.e., a plurality of NFs (AMF, AUSF, PCF, NRF, etc.).

For example, each NF such as AMF, AUSF, PCF, and NRF periodically reports its status information to the control node 300 at every occurrence of the predefined event, and transmits the status information to the NFs at the control node 300 The status can be monitored.

Here, the status information reported to the control node 300 includes information about the NF itself (e.g., NF ID, Common Function Handler (CFH) information H / W, S / W) and capability (Micro NF ID) and information about the micro NF itself (eg, micro NF ID) in units of control functions (including micro NF described below) mounted on the NF, capability (eg, available resource status), performance, interface, and so on.

The control node 300 transmits a specific control function of a specific NF that requires separation of control functions among a plurality of NFs to a plurality of NFs among the plurality of NFs based on a state monitoring for a plurality of NFs (AMF, AUSF, PCF, NRF, To be mounted on the selected NF.

More specifically, the control node 300 can request control function separation from a plurality of NFs to a specific NF requiring control function separation.

At this time, the control node 300 selects a specific NF that requires separation of control functions among a plurality of NFs according to a predefined policy, based on a monitoring state for a plurality of NFs (AMF, AUSF, PCF, NRF, etc.) .

For example, it is defined that an idle terminal in which a large number of signaling events may occur, such as an idle-to-active state, is selected to accommodate a certain number or more of NFs Can be assumed.

In this case, according to the assumed policy, the control node 300 receives a predetermined number or more of idle terminals among a plurality of NFs (AMF, AUSF, PCF, NRF, etc.) NF can be selected as a specific NF.

Alternatively, it may be assumed that a terminal subscribed to an ultra low-latency URLLC service is accommodated or a NF selected to select a certain rate or more of all the accommodating terminals is selected.

In this case, the control node 300 receives NFs of a plurality of NFs (AMFs, AUSFs, PCFs, NRFs, etc.) according to the above assumed policy, You can choose from a specific NF.

Of course, the policy definition described above is only one embodiment, and depending on how the policy is defined, a particular NF that needs to separate control functions will be selected differently.

Alternatively, regardless of the policy, the control node 300 may randomly or sequentially select a specific NF that requires separation of control functions among a plurality of NFs in a defined order.

Hereinafter, for convenience of explanation, it is assumed that AUSF, PCF, and NRF are selected as specific NFs requiring control function separation.

In this case, the control node 300 requests the control function separation to each of the specific NFs, that is, the AUSF, the PCF, and the NRF, which need to separate the control function.

The NF (for example, AUSF, PCF, NRF) receiving the control function separation request can distinguish a specific control function that can be separated based on user context information among at least one control function on which the control function separation request is installed .

At this time, the plurality of NFs may have the same classification policy for distinguishing specific control functions that can be separated based on the user context information, and may classify specific control functions that can be separated based on the user context information based on the same classification policy .

Here, the user context may indicate the area information of the terminal, the signaling state such as the idle / handover, the joined service type information (e.g., URLLC), etc. for each terminal (user).

For example, an NF (e.g., PCF) may be classified into an Attach situation (e.g., an idle-to-active state) in which a large number of received signals may be generated based on a user context of the accommodating terminal Can be divided into specific control functions that can be independently performed on an idle terminal and / or a terminal subscribed to the URLLC service.

In this case, the control function that can be independently performed can be a control function of the signaling processing unit, for example, a control function of the authentication procedure, a control function of the policy / management, (Eg, control functions such as switching, routing, load balancing, and packet encap / decap).

The NF (eg, AUSF, PCF, NRF) that receives the control function separation request can use the virtualized control function (hereinafter referred to as micro NF) to transfer the specified specific control function to another NF, And returns the user context information on the separated specific control function, that is, the micro NF, to the control node 300 in response.

Here, the user context information returned to the control node 300 is information on a specific control function, i.e., a terminal (user) subject to the micro NF.

For example, the user context information includes information including subscriber information and session information (UE ID, UE Capability, Slice ID, TE ID, QoS ID, Flow ID, Resource allocation, B / W, Latency, Lt; / RTI >

In the following description, the AUSF separates the virtualized control function (micro NF, m1), separates the virtualized control function (micro NF, m2) from the PCF, and the virtualized control function , Hereinafter, m3).

The control node 300 returns a user context information response to a specific control function that is detachable from the NF (e.g., AUSF, PCF, NRF) requesting the control function separation, that is, micro NF (e.g., m1, m2, m3) Based on the user context information returned from among a plurality of NFs (AMF, AUSF, PCF, NRF, etc.), other NFs capable of implementing the aforementioned micro NFs (e.g., m1, m2, m3) are selected.

That is, the control node 300 selects another NF capable of implementing the above-described micro NF (m1) based on the user context information returned from the AUSF, and based on the user context information returned from the PCF, (m2) can be selected, and another NF capable of implementing the aforementioned micro NF (m3) can be selected based on the user context information returned from the NRF.

At this time, the other NFs selected for the implementation of the micro NF (m2) separated from the PCF are connected to the terminal 1 by the signaling procedure PCF among the plurality of NFs (AMF, AUSF, PCF, NRF, And the NF at a position close to the position.

As shown in FIG. 2, in the signaling procedure with the terminal 1, the order of close proximity to the terminal 1 is AMF -> AUSF -> PCF -> NRF, so that implementation of micro NF (m2) Other NFs selected for the AMF or AUSF will be.

More specifically, the control node 300 determines the user context information returned from the PCF based on the monitoring status of the AMF and AUSF at a position closer to the terminal 1 than the PCF in the signaling procedure with the terminal 1 Considering one of AMF and AUSF as micro NF (m2), considering the lack of resources in the implementation of micro NF (m2), the latency not exceeding the critical level, proximity (distance) You can choose from other NFs that can be implemented.

Of course, the control node 300 determines whether to select AMF as another NF capable of implementing the micro NF (m1) in the same manner for the AUSF, and for the NRF, one of AMF, AUSF, (m3) can be selected.

Hereinafter, for convenience of explanation, it is assumed that AMF is selected as another NF capable of realizing micro NF (m1) of AUSF, micro NF (m2) of PCF, and micro NF (m3) of NRF.

In the present invention, NF for separating micro NF is referred to as Parent NF, and another NF for micro NF is referred to as Child NF.

The control node 300 may be configured to cause the specific control functions separated from the Parent NF (e.g., AUSF, PCF, NRF), i.e., micro NF (m1, m2, m3), and each user context information to be delivered to the Child NF To load the specific control functions micro NF (m1, m2, m3) into the Child NF (eg AMF).

For example, the control node 300 may provide the separated specific control functions, i.e. micro NF and related user context information, in the Child NF (e.g., AMF) described above, in each of the Parent NF (e.g., AUSF, PCF, NRF) .

Each of AUSF, PCF and NRF provides AMF with micro NF (m1, mi) to the AMF by providing (e.g., cache, migrate) the micro NF and related user context information, m2, m3) can be mounted.

For example, the PCF is a message in which the micro-NF (m2) separated by itself and the cacheable information (e.g., micro NF ID, user context identification information, etc.) Can be provided in AMF (Cache).

Therefore, the AMF can acquire micro NF (m2) according to the micro NF ID based on the information (e.g., micro NF ID, user context identification information, etc.) . The AMF can then acquire micro NF (m2) according to the micro NF ID from the PCF or from a separate, specific data repository.

For example, the PCF may provide the micro NF (m2) separated by itself as AMF, and also provide the AMF with information about the user context (e.g., user context identification information) related to the micro NF (m2) However, information (for example, user context identification information) stored in itself can be deleted (Migration).

Alternatively, the control node 300 may allow the specific control functions separated from the Parent NF (e.g., AUSF, PCF, NRF), i.e. micro NF and associated user context information, to be copied to the Child NF .

Each of the AUSF, PCF and NRF permits access from the AMF to copy the micro NF and related user context information that it has separated according to the command of the control node 300 and transmits the micro NF (m1 , m2, m3) can be mounted.

For example, the PCF may allow access from the AMF to copy information about the micro NF (m2) and its associated user context (e.g., user context identification information) that it has separated (Copy).

Accordingly, the AMF can access / copy / acquire (Copy) the micro NF (m2) in the PCF and information (e.g., user context identification information) related to the user context related thereto.

As described above, according to the embodiment of the present invention, the inherent control function that is statically installed in the network node NF of the Control / User Plane in the 5G is used as the control function of the other NF, The control function moving technique that can be moved / mounted to the other NF of the position is realized.

Accordingly, in the present invention, it is possible to reduce the signaling processing delay for the UE by reducing the signaling between each NF in the signaling process for the UE based on the control function movement technique realized as described above.

Hereinafter, a network device (network node, NF) capable of realizing a control function movement technique proposed in the present invention and capable of reducing signaling between NFs will be described in detail.

4, the network device 100 of the present invention includes a control function unit 110, a separation unit 120, and a control unit 130. [

The network device 100 of the present invention described below can mean NF corresponding to Parent NF in view of the control function moving technology of the present invention.

The control function unit 110 carries at least one control function.

For example, in the case where the network device 100 of the present invention is a PCF, the control function unit 110 controls the control function of the signaling processing unit, for example, the control function of the policy / management, the control function of the operation unit in the signaling processing, And the like.

The separating unit 120 separates a specific control function that can be separated based on the user context information from among at least one control function installed in the control function unit 110 to separately generate a specific control function.

More specifically, when receiving the control function separation request from the control node 300, the separator 120 separates and separates, based on the user context information, at least one control function installed in the control function unit 110 It is possible to distinguish possible specific control functions.

At this time, the separator 120 can classify specific control functions that can be separated based on the user context information, based on the same classification policy that a plurality of NFs have to separate specific control functions that can be separated based on the user context information have.

For example, based on the user context of the accommodated terminal (user), the separating unit 120 may extract an Attach status (e.g., Idle a control function capable of independently performing an operation on an idle terminal and / or a terminal subscribed to a URLLC service, which is expected to be in the -to-Active state, can be distinguished as a separable specific control function.

In this case, the control function that can be independently performed can be a control function of the signaling processing unit, for example, a control function of the authentication procedure, a control function of the policy / management, (Eg, control functions such as switching, routing, load balancing, and packet encap / decap).

Accordingly, if the separable specific control function is classified, the separating unit 120 can separately generate a virtualized control function (hereinafter referred to as micro NF) so that the specific control function can be transferred to another NF.

At this time, the separately generated micro NF will be generated including all the logic and resources necessary for independently performing the corresponding specific control functions.

The control unit 130 provides at least one of the micro NF and the related user context information separated and generated by the separation unit 120 to the control node 200 so that the control node 200 transmits the user context information Such as the micro NF described above, to be mounted on another selected network device, i.e., another NF.

For example, the control unit 130 may respond to the control function separation request received from the control node 300 in response to the specific control function separated or generated in the separating unit 120, that is, the user context information about the micro NF, And provide it to the control node 200.

Here, the user context information for the micro NF is information on the terminal (user) that is the target of the specific control function separately generated, micro NF.

For example, the user context information includes information including subscriber information and session information (UE ID, UE Capability, Slice ID, TE ID, QoS ID, Flow ID, Resource allocation, B / W, Latency, Lt; / RTI >

Hereinafter, for convenience of explanation, it is assumed that the network device 100 of the present invention is a PCF, and a specific control function generated by the network device 100 of the present invention, that is, micro NF is m2.

The control node 300 is capable of implementing micro NF (m2) generated separately from the network device 100 (PCF) based on the user context information returned from the network device 100 (PCF) of the present invention. You will choose NF.

At this time, the other NFs selected for the implementation of the micro NF (e.g., m2) of the network device 100 (e.g., PCF) are subjected to the signaling procedure with the terminal 1 among a plurality of NFs (AMF, AUSF, PCF, NRF, Or AUSF at a location closer to terminal 1 than upper network device 100 (e.g., PCF).

Hereinafter, for convenience of explanation, it is assumed that AMF is selected as another NF selected for implementation of micro NF (m2) separated and generated in the network device 100 (PCF) of the present invention.

In this case, the network device 100 (PCF) becomes Parent NF and AMF becomes Child NF on the basis of the micro NF (m2) separated and generated in the network device 100 (PCF) of the present invention.

Then, the control node 300 instructs the parent NF, that is, the network device 100 (PCF), to provide separately generated micro NF (m2) and related user context information to Child NF, i.e., AMF, Copy)

The control unit 130 provides (e. G., Cache, Migration) micro NF (m2) and associated user context information separately generated by the AMF selected by the other network device, i.e., the control node 300, Allow access from the AMF to copy the generated micro NF (m2) and related user context information (Copy), and allow the micro NF (m2) to be loaded on the Child NF, AMF.

As described above, according to the network device 100 of the present invention, the inherent control function (micro NF) that is statically mounted in the network node NF in the 5G can be transmitted to other NFs, It is possible to realize a control function moving technique that can be separated and mounted to other NFs located at a position close to the center.

In this case, since the specific control function (micro NF (m2)) performed in the PCF is moved / mounted to the AMF located closer to the terminal than the PCF, the terminal 1 is specified as the target of the user context information micro NF The signaling between the AMF and the PCF can be handled within the AMF.

Thus, according to the present invention, the number of signaling can be significantly reduced in the signaling process for a terminal defined in 5G.

Furthermore, the control function unit 110 determines whether or not micro NF (m2) among the at least one control function currently installed according to the update information received from the micro NF (m2) of Child NF, that is, Can be updated and managed.

Specifically, a specific control function (micro NF (m2)) performed in the network device 100 (PCF) is moved / mounted on the AMF, and the terminal 1 is specified as the target of the user context information micro NF The specific signaling to be transmitted (transmitted) to the network device 100 (PCF) in the signaling procedure for the MS NF (m2).

In this case, it is necessary to know what kind of execution / processing has been performed on a terminal (user) in the micro NF (m2) in the AMF instead of the original specific control function installed in the network device 100 (PCF).

To this end, the child NF, that is, the micro NF (m2) of the AMF, transmits update information (or result information) related to the signaling process directly to the network device 100 (PCF) Lt; / RTI >

Alternatively, the child NF, that is, the micro NF (m2) of the AMF, stores update information (or result information) related to the signaling process every time signaling is processed, and stores the accumulated / 100, PCF) or directly via the control node 300.

Accordingly, the control function unit 110 may be configured to update at least one of the at least one control function that is installed in advance according to the update information (or the result information) received from the Child NF, that is, the micro NF (m2) it is possible to update and manage information related to the original specific control function corresponding to micro NF (m2).

Therefore, from the viewpoint of the original specific control function mounted on the network device 100 (PCF), it is possible to control which terminal (user) has performed / processed in micro NF (m2) in AMF instead of itself do.

Meanwhile, the network device 200 of the present invention shown in FIG. 5 shows a network node NF corresponding to the Child NF in view of the control function moving technology of the present invention.

The network device (200) of the present invention includes a control function unit (210) and a control unit (230).

In addition, the network device 200 of the present invention may further include a separator 220, in which case the network device 200 may operate as the Parent NF described above.

The control function unit 210 includes at least one control function.

For example, if the network device 200 of the present invention is an AMF, the control function unit 210 may control the control function of the signaling processing unit, for example, the control function of the radio section access, the control function of the operation unit in the signaling processing, , Load balancing, and other control functions.

The control unit 230 can obtain a specific control function (micro NF) separately generated based on the user context information in the other network device, e.g., Parent NF (e.g., PCF).

Specifically, the control unit 230 can recognize a specific control function of the parent NF (e.g., PCF) to be moved / mounted from the control node 300, that is, micro NF (m2).

The control unit 230 provides a control function of the parent NF (e.g., PCF), that is, the micro NF (m2) and related user context information, from the control node 300 or from the Parent NF (Eg, Cache, Migration) or accessing Parent NF (eg PCF) to copy micro NF (m2) and related user context information. micro NF (m2) can be obtained.

Accordingly, the control unit 230 acquires a specific control function, i.e., micro NF (m2) separated from the parent NF (e.g., PCF), and loads the specific control function of the other NF, that is, the PCF, .

In this case, each of the control functions installed in the control function unit 210 may be configured to transmit specific signaling according to user context information to be transmitted to another NF, that is, a PCF specific control function during signaling to the terminal, To the specific control function of the control unit 230, that is, micro NF (m2), so that specific signaling is processed in the network device 200 (AMF).

Specifically, each of the control functions installed in the control function unit 210 performs a control function in a process of signaling to the terminal through the execution of a control function, wherein the user context information of the moved / mounted micro NF (e.g., m2) , It is possible to distinguish terminals specified as targets of micro NF (for example, m2).

Hereinafter, for convenience of explanation, it is assumed that the terminal 1 is a terminal (user) specified by an object of micro NF (e.g., m2).

Each control function installed in the control function unit 210 in the course of processing signaling for a terminal (a specific terminal that is a target of the micro NF (m2)) through the execution of a control function, The specific signaling according to the user context information to be transmitted to the specific control function of the PCF is transmitted to the micro NF (m2) of the control unit 230 instead of being transmitted to the PCF.

In this case, a specific control function (micro NF (m2)) moved / mounted on the network device 200 of the present invention is transmitted to the terminal 1 specified by the user context information micro NF (m2) Since the specific signaling can be handled in place of the PCF in the signaling process stop, the existing AMF and PCF signaling can be processed within the network device 200 (AMF).

Further, each of the control functions installed in the control function unit 210 can be used to determine whether or not there is a shortage of resources for performing micro NF (e.g., m2) of another NF (e.g., PCF) Signaling for the terminal 1 that has signaled to the NF (e.g., PCF) of the mobile / mounted micro NF (e.g., m2)) to the original specific control function loaded on another NF (e.g., PCF) .

On the other hand, the micro NF (eg m2) of another NF (eg PCF) that is moved / mounted can be used for a predetermined hold time after mounting, or for certain control functions (eg micro NF eg m2) The control unit 230 can hold the resource until the resource shortage occurs.

Therefore, each control function installed in the control function unit 210 can be used for a specific signaling (that is, a control signal) when the mount retention time of micro NF (e.g., m2) of another NF (e.g., PCF) The signaling for the terminal 1 that has delivered to the NF (e.g., PCF) of the mobile / mounted micro NF (e.g., m2) can be delivered to the original specific control function loaded on another NF (e.g., PCF) .

As described above, according to the network device 200 of the present invention, the inherent control function (micro NF) stably installed in the network node NF in the 5G is transmitted to other NFs, in particular, It is possible to realize a control function moving technique that can be separated and mounted to other NFs located at a position close to the center.

Hereinafter, with reference to FIG. 6, a brief description will be given of a situation in which signaling between NFs is reduced by the present invention in an Attach situation (e.g., idle-to-active) in which the terminal 1 accesses the core network as shown in FIG. would.

6, it is assumed that a micro NF (e.g., m1, m2, m3) generated and separated from each of AUSF, PCF, and NRF is moved / mounted on the AMF based on the control function movement technique.

It is assumed that the terminal 1 is a terminal specified by all of m1, m2, and m3 based on user context information of m1, m2, and m3, respectively.

As shown in FIG. 6, the terminal 1 is connected to an access terminal, that is, a wireless section through signaling with the AMF through the base station 10. [

When the radio section is connected, the terminal 1 transmits an Attach Request message for accessing the core network to the AMF. The AMF (original control function) is an A / M1 is a policy for requesting a policy for the terminal 1 from the PCF to be moved / mounted from the PCF instead of the PCF performing the control function of the policy / management, Message.

In this case, m2 returns a response message to the terminal m1 in response to the policy such as subscription service information and billing to the terminal 1, and m1 performs the authentication procedure for the terminal 1 based on the returned policy And returns a response message to the AMF (original control function) responding to the authentication result (for example, authentication success).

Therefore, the AMF (original control function) transmits an N / W information message requesting information (hereinafter, N / W information) about each network node NF related to the terminal 1 from the NRF instead of the NRF m3 and responds to the response message, and then transmits an Attach Complete message informing the terminal 1 of completion of the core network connection.

After the terminal 1 receives the Attach Complete message and the core network connection is completed, the terminal 1 can transmit and receive data to the data network (e.g., the Internet) through the data node of the user plane, that is, the UPF.

As can be seen from the description with reference to FIG. 6, comparing the signaling (a 'in FIG. 6) according to the control function movement technique of the present invention with the existing signaling (FIG. 2 a) The number of signaling between AMF, AUSF, PCF, NEF, etc. can be significantly reduced.

Therefore, according to the present invention, when compared with the conventional signaling, compared to the conventional signaling, the delay caused by the control signaling process for the terminal 1 is changed according to the number of signaling operations, of _a t - can be reduced as much as in FIG. 56 t _{a '),} This can speed up the service start time to send and receive actual data.

Particularly, according to the control function moving technique of the present invention, there is no need to change the design in the terminal of the user, and the inconvenience caused by the movement / mounting of the control function can not be experienced at all.

Accordingly, the present invention realizes a control function movement technique capable of moving / loading a control function mounted on the network node (NF) to another NF, thereby reducing signaling between each NF in the signaling process for the terminal, The effect of reducing signaling processing delay and the effect of efficiently supporting the demand / performance of the service type supported by 5G is derived.

Hereinafter, a method of operating a network device (network node) according to an embodiment of the present invention will be described in detail with reference to FIG.

The network device of the present invention may be a Parent NF that separates / generates a mounted control function, and may be a Child NF that moves / loads a control function (micro NF) of another NF.

Hereinafter, with reference to FIG. 7, the operation flow in the case where the network device of the present invention is Parent NF and the operation flow in the case of Child NF will be separately described for ease of explanation. First, I will explain.

The network device NF of the present invention reports its own status information to the control node 300 (S100), periodically or at every predefined event occurrence, The status can be monitored.

Accordingly, the control node 300 can select a specific NF requiring control function separation among a plurality of NFs based on a state monitoring for a plurality of NFs (AMF, AUSF, PCF, NRF, etc.).

When the network device NF of the present invention is selected as a specific NF requiring control function separation from the control node 300, the network device NF receives a control function separation request (S110 Yes).

When receiving the control function separation request (Yes in S110), the network device NF of the present invention can distinguish a specific control function that can be detached based on the user context information of at least one control function on which the network device NF is mounted (S120).

For example, the network device NF of the present invention is capable of detecting an Attach situation (e.g., Idle-to) in which a large number of signaling among the accommodated terminals may occur based on the user context of the accommodated terminal A control function capable of independently performing an operation on an idle terminal and / or a terminal subscribed to the URLLC service can be classified into a detachable specific control function.

The network device NF of the present invention separates and generates a specific control function that has been divided into a virtualized control function (hereinafter referred to as micro NF) so as to be transferable to another NF, The control node 300 can respond to the generated specific control function, that is, the user context information for the micro NF (S140).

When the user context information response to the specific control function that is detachable from the NF requesting the control function separation, that is, the micro NF, is returned, the control node 300 transmits the returned user context of the plurality of NFs (AMF, AUSF, PCF, NRF, Based on the information, it is possible to select other NFs capable of implementing the aforementioned micro NF.

Then, the control node 300 instructs the network device NF of the present invention, which is Parent NF, to provide the separately created specific control function, that is, the micro NF and the related user context information, to the above-mentioned selected Child NF, NF and the copy from the Child NF for the associated user context information.

Accordingly, the network device NF of the present invention provides micro NF and related user context information separately generated (e.g., Cache, Migration) to another NF selected by the control node 300, i.e., Child NF, The micro NF can be moved / mounted in a manner that permits access and copying of the micro NF.

According to the update information (or the result information) received from the micro NF of the Child NF, which is moved / loaded from itself, either regularly or on a predetermined period basis, the network device NF of the present invention has at least one control The micro NF (m2) in the AMF instead of the original specific control function installed in the network device 100 (PCF) by updating and managing the information relating to the original specific control function corresponding to the micro NF among the functions (S160) The user can manage / manage the execution / processing of a terminal (user).

Hereinafter, an operational flow in the case where the network device of the present invention is a parent NF will be described.

The network device NF of the present invention recognizes whether another NF is selected as the child NF for micro NF movement / placement of the parent NF from the control node 300 (S170).

For example, the network device NF of the present invention can recognize that a specific control function of the parent NF to be moved / loaded from the control node 300, that is, micro NF, is selected as Child NF (S170 Yes) ).

The network device NF of the present invention determines whether the child node NF is selected as the child NF (Yes in S170), from the control node 300 or from the parent NF, which is another NF, the specific control function of the parent NF, (Eg Cache, Migration), or by accessing Parent NF and copying the micro NF and related user context information, it is possible to acquire and mount the specific control function separated by Parent NF, ie micro NF (S180).

Therefore, the network device NF of the present invention transmits specific signaling according to user context information to be transmitted to a specific control function of another NF, that is, Parent NF, during the signaling to the terminal, instead of transferring the specific signaling to the Parent NF, To the micro-NF, to process the specific signaling within the network device NF (S190).

At this time, the network device NF of the present invention always transmits update information (or result information) related to the signaling process to the Parent NF at any time whenever signaling is processed in a specific control function to be moved / mounted, that is, micro NF, (Not shown).

Alternatively, the network device NF of the present invention stores the update information (or result information) related to the signaling process every time the specific control function, i.e. micro NF, processes the signaling, (Or result information) stored in the Parent NF directly or through the control node 300. [

In addition, the network device NF of the present invention is capable of performing a control function other than the resource for performing the original control functions mounted on the network device NF, that is, a lack of resources for performing the micro NF of the moved / mounted Parent NF (S200 Yes), the micro NF of the moved / mounted Parent NF is deleted and the signaling for the terminal 1 that has transmitted the micro NF to the corresponding micro NF is transmitted to the parent NF (S210).

Alternatively, the network device NF of the present invention deletes the micro NF of the moved / mounted Parent NF when the mounting retention time has elapsed after the mounted micro NF of the moved / mounted Parent NF has passed (Yes in S200) The signaling for the terminal 1 that has been transferred to the NF may be transmitted to the parent NF (S210).

As described above, according to the network system according to the embodiment of the present invention, the network apparatus applied thereto, and the operation method of the apparatus, it is possible to move / mount the control function mounted on the network node NF to another NF The present invention realizes a control function movement technology and reduces the signaling delay for the terminal by reducing the signaling between each NF in the signaling processing for the terminal. Thus, the demand / performance of the service type supported by 5G can be efficiently The effect is supported.

Meanwhile, FIG. 8 illustrates a method of operating a network node according to an exemplary embodiment of the present invention, and specifically, an operation method of processing signaling at a network node (NF).

As described above, the network node NF of the present invention corresponds to the network nodes of the Control Plane and User Plane, that is, AMF, AUSF, PCF, NRF, UPF, and the like.

According to the method of operating the network node NF of the present invention, the network node NF is equipped with at least one control function for its own operation (S300).

9, a network node (e.g., NF1) is based on the implementation of at least one control function for operating a network node (e.g., NF1), micro NF (hereinafter mNF) .

Each mNF mounted on a network node (e.g., NF1) may be an mNF preloaded on a network node (e.g., NF1) or may be an mNF moved / mounted from another NF (parent NF) have.

According to the method of operation of the network node NF of the present invention, the network node NF processes this signaling for signaling of the terminal through at least one mNF-performed and mNF-carried-in-the-network node NF S310 to S350).

According to the method of operating the network node NF of the present invention, each time the signaling is processed in each mNF during the processing of the signaling, the network node NF stores the result information related to the signaling processing in a specific data store, (S330).

According to the embodiment of the present invention, the control function, that is, the mNF may be composed of at least one component having a software form in order to perform the control function of the mNF itself.

That is, the component can be a minimum unit for performing the control function of the mNF, for example, S / W Code Patch, Library, Package, and Plug-In.

That is, one mNF is configured of at least one component having at least one of S / W Code Patch, Library, Package, and Plug-In, and is configured to perform control functions of mNF based on at least one component configured as described above Lt; / RTI >

And, according to a more specific embodiment, each component may have the function of a signaling input, a signaling process, and a signaling output.

Therefore, the mNF, which is composed of components having the functions of signaling input / process / output, does not have the information necessary for performing the control function of the mNF itself and / Can support stateless behavior.

Hereinafter, a process (S310 to S350) of processing signaling of a terminal related to a specific service in the network node NF of the present invention will be described in detail.

9, in order to provide a specific service (hereinafter, Service 1) to a terminal (user), a plurality of NFs (NF1,2 ... N) support Service 1.

The network node NF of the present invention will be described on the assumption that it is one of a plurality of NFs (NF1,2 ... N) that support Service 1 and is NF1.

As shown in Fig. 9, the network node (e.g., NF1) of the present invention mounts a plurality of mNFs for operation of a network node (e.g., NF1) itself.

According to the method of operating the network node NF of the present invention, when signaling is received (inputted) by the terminal related to the service 1 (S310), the mNF (first processing entity) in the network node And performs signaling processing by performing its own control function at step S320.

In this case, since mNF is composed of components having functions of input / input / output / output, it supports stateless operation. Therefore, information (eg, user context) necessary for processing signaling is transmitted to Service 1 (hereinafter, DB) associated with a particular database.

The mNF, which is the main processing entity, is composed of components having functions of signaling input / process / output and supports stateless operation. Therefore, the network node (for example, NF1) If there is an mNF which is the subject of next processing (Yes in S340), the necessary signaling is transferred (output) to the next processing entity mNF, and the result information related to this processing is not held.

Meanwhile, according to the method of operating the network node (NF) of the present invention, the result information according to the signaling process in the first processing entity mNF is stored in a specific data storage associated with Service 1 (S330).

Here, the result information may include a control function that has performed the signaling process, that is, state information of the mNF that is the performing entity, and user context information on at least one of the service of the terminal and the signaling, that is, Service 1.

The network node (e.g., NF1) of the present invention may include a CFH (Common Function Handler) for linking / controlling / managing a plurality of mNFs.

CFH can be a structure including H / W configuration and S / W OS with NFV (Network Function Virtualization) Instruction, and can be used for NFVI (Infrastructure as a Service), IaaS (Infrastructure as a Service) and Platform as a Service (PaaS) . ≪ / RTI >

Specifically, CFH has compatibility / dependency rules for mNFs constituting NF (for example, NF1), and based on these rules, each mNF communicates with each other or transmits (outputs) signaling according to a signaling procedure And can provide necessary information from the DB in each mNF and provide the result information according to the signaling process in each mNF in the DB to perform interworking / control / management.

FIG. 10 is an exemplary diagram illustrating information about micro NF according to an exemplary embodiment of the present invention. Referring to FIG.

In FIG. 10, the contents of the information on the mNF are shown assuming one mNF constituting the NF supporting the IoT service.

As shown in FIG. 10, the information on the mNF may include a micro NF name or a micro NF ID, a form and a version of each component, a description of each component, resource related information of each component, and the like .

The CFH can manage the information as shown in FIG. 10 for each mNF constituting the NF (for example, NF1).

Therefore, according to the network node (NF) operating method of the present invention, the result information according to the signaling process in the mNF, which is the first processing entity, can be stored in the DB by CFH (S330).

In addition, according to the method of operating the network node NF of the present invention, when signaling is received (inputted) by the terminal related to the service 1 (S310), the first processing subject in the network node (e.g., NF1) When the signaling is transmitted from the mNF serving as the second processing entity to the mNF serving as the second processing entity, the second processing entity, mNF, performs its control function to process the signaling (S320).

At this time, since mNF supports stateless operation, information necessary for signaling processing can be acquired / used in the DB through CFH.

Also, according to the network node (NF) operating method of the present invention, the result information according to the signaling process in the mNF, which is the second processing subject, can be stored in the DB by CFH (S330).

Since the mNF, which is the main processing entity, supports the stateless operation, if the mNF that is the next processing subject in the network node (e.g., NF1) exists (Yes in S340) according to the signaling procedure, the necessary signaling is transmitted to the next processing entity, mNF (Output) the signaling to the next NF (e.g., NF2) supporting the other NF, i.e., Service 1 (S350).

As described above, according to the embodiment of the present invention, each mNF in the network node NF performs stateless operation by performing its own control function to process the signaling, and all of the mNFs related to the signaling process in each mNF The result information is stored in the stateful DB, and realizes the NF signaling process.

According to the signaling processing structure of the NF, the effect of easily generating mNF in the NF as required can be expected.

For example, if there is an mNF that operates abnormally in the NF, mNF supports stateless operation. Therefore, even if mNF that operates abnormally is deleted and mNF of the same control function is newly loaded, all information (for example, state information, Context information) is stored, the NF will normally be able to process the signaling.

A method of operating a network device (network node) according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through a variety of computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the network system according to the present invention, the operation of the network device and the operation of the device, and the operation method of the network node, the control function moving technology capable of moving / loading the control function mounted on the network node (NF) It is not only the use of related technology but also the possibility of commercialization or operation of the applied device is sufficient and it is practically possible to carry out clearly, Invention.

100: Network device (network node)
110: control function unit 120:
130:

Claims (19)

A plurality of network nodes carrying at least one control function; And
And a control node for causing a specific control function of a specific network node, which is required to separate control functions among the plurality of network nodes, to be mounted on another selected one of the plurality of network nodes. The method according to claim 1,
The control node,
When a context information response to a specific control function detachable from the specific network node is returned,
And selects another network node capable of implementing the specific control function based on the context information among the plurality of network nodes. 3. The method of claim 2,
The control node,
The specific control function and the context information separated from the specific network node are transferred to the other network node, and the specific control function is loaded on the other network node. In a network device,
A control function unit for mounting at least one control function;
A separator for separating a specific control function separable from the at least one control function based on user context information to separate the specific control function;
And a control unit for providing at least one of the separated specific control function and the user context information to the control node so that the specific control function can be mounted on another network device selected on the basis of the user context information by the control node And the network device. 5. The method of claim 4,
The other network device includes:
Wherein the network device is one of a plurality of network devices, the network device being in a position closer to the terminal than the network device in a signaling procedure with the terminal. 5. The method of claim 4,
Wherein,
The network device may provide the specific control function and the user context information to the another network device or permit copying from the other network device to the specific control function and the user context information, The function of the network device is implemented. 5. The method of claim 4,
The control function unit,
And updates and manages information related to the specific control function among the at least one control function in accordance with update information received at any time or on a predetermined period basis from the specific control function of the other network device. In a network device,
A control function unit for mounting at least one control function; And
And a control unit for acquiring a specific control function separated from other network devices based on the user context information and mounting the specific control function of the other network device on the network device;
Wherein each control function of the control function unit comprises:
Transmitting a specific signaling according to the user context information to be transmitted to a specific control function of the other network device during signaling to the terminal to the specific control function of the control section so that the specific signaling is processed in the network device Characterized by a network device. 9. The method of claim 8,
The specific control function includes:
Wherein the control unit is mounted and held in the control unit during a predetermined holding period after the mounting, or until a time when a resource shortage occurs to perform the specific control function other than the resource for performing the control function of the control function unit. . 9. The method of claim 8,
Wherein each control function of the control function unit comprises:
Wherein the control unit transmits the specific signaling to a specific control function of the other network device when a resource shortage occurs to perform the specific control function other than the resource for performing the control function of the control function unit. A method of operating a network device,
A separation step of separating a specific control function that can be separated based on user context information among at least one control function installed in the system; And
And a function control unit for providing at least one of the separated specific control function and the user context information to the control node so that the specific control function can be mounted on another network device selected on the basis of the user context information by the control node ≪ / RTI > 12. The method of claim 11,
The control node provides the specific control function and the user context information to the other network device or permits the copying of the specific control function and the user context information from the other network device, Further comprising the step of causing the network device to load the specific control function. 12. The method of claim 11,
Updating the information related to the specific control function among the at least one control function according to the update information received at any time or on a predetermined period basis from the specific control function of the other network device A method of operating a network device. A method of operating a network device,
Loading at least one control function;
Acquiring a specific control function separated on the basis of the user context information from another network device and mounting the specific control function of the other network device on the network device;
Wherein the at least one control function transmits specific signaling according to the user context information to be transmitted to a specific control function of the other network device during signaling to the terminal to the specific control function of the control part, And a signaling step for causing the specific signaling to be processed. 15. The method of claim 14,
The specific control function includes:
Wherein the network device is mounted on the network device for a predetermined holding period after the mounting, or until a time when a resource shortage occurs to perform the specific control function other than the resource for performing the control function of the control function section. Method of operation of the device. 15. The method of claim 14,
The at least one control function may include transmitting a specific signaling to a specific control function of the another network device when a resource shortage occurs to perform the specific control function other than a resource for performing a control function of the control function unit Further comprising the step of: A method of operating a network node supporting a particular service,
Loading at least one control function for operation of the network node;
Processing the signaling for signaling of the terminal through the at least one control function and between the control functions;
And storing result information associated with the signaling process in a specific data store associated with the particular service and not being retained in the control function each time the signaling is processed in each control function. Way. 18. The method of claim 17,
Wherein the result information includes status information of a control function that has performed signaling processing, and user context information of at least one of the terminal and the signaling service. 18. The method of claim 17,
The control function includes:
And at least one component having a software form for performing the control function,
Wherein the at least one component comprises:
A signaling input, a signaling process, and a signaling output.

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