KR102425424B1 - Operating method of mme and operating method of amf for providing integrated dedicated network service - Google Patents

Abstract

A method of operating an MME and an operating method of an AMF for an integrated dedicated network service are provided. This method is a method of operation of a Mobility Management Entity (MME), the MME receiving a terminal access request from a base station, receiving network selection indication information of the terminal from a subscriber device, based on the network selection indication information determining the access request as a dedicated network access request; and requesting a dedicated SMF (Session Management Function) connected to a dedicated UPF (User Plane Function) to create a dedicated data session for private network access.

Description

Operation method of MME and operation method of AMF for integrated dedicated network service

The present invention relates to a method of operating an MME and an AMF for an integrated private network service, and relates to a technology for separating a public network and a private network through a core network.

As the broadband mobile communication market has been activated and the penetration rate of smartphones has increased, the demand for using broadband mobile communication and smartphones for corporate services has increased. In particular, with the spread of Bring Your Own Device (BYOD) services, the number of companies using personal devices for business purposes is rapidly increasing. However, when a privately owned terminal accesses an internal computer network, a security problem may occur due to information leakage. To prevent this, a Private Long Term Evolution (LTE) service is provided.

Private LTE service is provided to subscribers by dividing the core network into a dedicated network such as a corporate network and a public network such as the Internet network. Since the Private LTE service is aimed at corporate subscribers, it can also be referred to as a corporate-only LTE service. Private LTE service is a B2B-specialized service that enables users to conveniently use and secure subscriber data at once.

Customers subscribe to corporate-only parent line products based on monthly data provision (300GB to 50TB), and customer employees sign up for corporate-only LTE supplementary service products and install corporate-dedicated LTE apps on their personal terminals to access corporate networks. can

These enterprise-only LTE services are equally applied to 5G, and the service name can be called enterprise-only 5G service. Unlike the enterprise-only LTE service, not only 5G terminals but also LTE terminals can subscribe to enterprise-only 5G additional service products.

For enterprise-only LTE service, the network switching function between public and private networks was provided only for LTE terminals that used LTE Universal Subscriber Identity Module (USIM) and subscribed to the LTE plan.

However, if the corporate 5G service uses 5G USIM and is designed to allow network switching only for 5G terminals subscribed to the 5G plan, from the network operator's point of view, public networks, corporate-only LTE networks, and corporate-only 5G networks are managed respectively. There are inconveniences to be had. In addition, from the customer's point of view, it is necessary to subscribe to the enterprise-only LTE service and the enterprise-dedicated 5G service, respectively, so it may experience difficulties in service scalability due to overlapping investment.

The problem to be solved by the present invention is to selectively connect a terminal among the LTE core network and the 5G core network according to the combination of the terminal type, USIM type, and rate plan type in a network environment in which the LTE core network and the 5G core network are mixed, and the terminal type , the operation method of MME (Mobility Management Entity) and AMF (Access and Mobility Function), which accommodates all subscribers regardless of USIM type and rate plan type and provides integrated private network service that enables network switching between public and private networks. will provide

According to one embodiment of the present invention, there is provided a method of operating a Mobility Management Entity (MME), the MME receiving a terminal access request from a base station, receiving network selection indication information of the terminal from a subscriber device, the determining the access request as a dedicated network access request based on network selection indication information, and requesting a dedicated SMF (Session Management Function) connected to a dedicated UPF (User Plane Function) to create a dedicated data session for dedicated network access include

In the method of operation of the MME, the step of receiving the network selection indication information includes further receiving core selection indication information, and after receiving the network selection indication information, the access request based on the network selection indication information Determining as a public network access request, determining the terminal as a 5th generation (5G) terminal based on the core selection indication information, and sending a re-route message including the access request to AMF (Access and Mobility Management Function).

After determining the public network access request, determining the terminal as a Long-Term Evolution (LTE) terminal based on the core selection indication information, and a Serving Gateway (SGW) to which a Packet Data Network Gateway (PGW) is connected It may further include the step of requesting to create a public data session for access to the public network.

Between receiving the access request and receiving the network selection indication information, the terminal uses an LTE Universal Subscriber Identify Module (USIM) based on an International Mobile Subscriber Identity (IMSI) band included in the access request. Further comprising the step of determining whether or not to use a 5G USIM, the step of receiving the network selection indication information, the network selection indication information and the core selection indication information of the terminal using the LTE USIM from HSS (Home Subscriber Server) , or may receive network selection indication information and the core selection indication information of a terminal using 5G USIM from Unified Data Management (UDM).

According to another embodiment of the present invention, as a method of operating a Mobility Management Entity (MME), the MME receives a terminal access request from a base station, and receives network selection indication information and core selection indication information of the terminal from a subscriber device. determining whether the access request is a public network access request or a private network access request based on the network selection indication information; if the access request is a private network access request, a dedicated Session Management Function (SMF) and a dedicated UPF determining (User Plane Function) as a core node to connect the terminal and a dedicated data session, and when the access request is a public network access request, based on the core selection indication information to connect the terminal and the public network data session determining a core node.

The step of determining the core node to which the public network data session will be connected may include, if the core selection indication information indicates an LTE terminal, a Serving Gateway (SGW) and a Packet Data Network Gateway (PGW) as a core node to which the public network data session will be connected. can decide

The step of determining a core node to which the public network data session will be connected includes, if the core selection indication information indicates a 5G terminal, transmitting a re-route message including the access request to the base station, and , the access request included in the path change message is transmitted from the base station to an Access and Mobility Management Function (AMF), and the public network data session may be connected between the core node determined by the AMF and the terminal.

The core node to which the public network data session will be connected, when the core selection indication information indicates a 5G terminal that uses a 5G Universal Subscriber Identify Module (USIM) and subscribes to a 5G plan, it may be determined as a public SMF and a public UPF.

The core node to which the public network data session will be connected is a Serving Gateway (SGW) and a Packet Data Network Gateway (PGW) when the core selection indication information indicates a 5G terminal using an LTE USIM or subscribed to an LTE plan. have.

According to another embodiment of the present invention, as a method of operating an Access and Mobility Management Function (AMF), the AMF receiving an access request of a terminal from a base station, receiving network selection indication information of the terminal from a subscriber device , determining the access request as a public network access request based on the network selection indication information, and requesting a common SMF (Session Management Function) connected to a common UPF to create a common data session, The network access request may be included in a re-route message transmitted by a Mobility Management Entity (MME) to the base station.

After receiving the network selection indication information, determining the access request as a dedicated network access request based on the network selection indication information, and dedicated to a dedicated SMF (Session Management Function) connected to a dedicated UPF (User Plane Function) The method may further include requesting creation of a data session.

In the receiving of the network selection indication information, core selection indication information is further received, and the request for creation of the public data session is, the core selection indication information uses a 5G Universal Subscriber Identity Module (USIM) and subscribes to a 5G plan In the case of indicating one 5G terminal, it may be transmitted through the public SMF.

After determining as the public network access request, if the core selection indication information indicates a terminal that does not use a 5G USIM or a 5G terminal that is not a 5G plan, requesting the SGW (Serving Gateway) to create a public data session The method further includes, wherein the public data session is established by the SGW between a Packet Data Network Gateway (PGW) and the 5G terminal and can be used for data transfer transmitted/received between the 5G terminal and the public network connected to the PGW.

The base station that has transmitted the route change message to the AMF is an eNB (eNodeB), and the common UPF or the dedicated UPF may transmit/receive user data to and from the terminal through a gNB (gNodeB).

According to the embodiment, by providing a corporate-only 5G network structure that can integrate and accommodate LTE terminals and 5G terminals, network switching between public and private networks is facilitated by accommodating all subscribers regardless of terminal type, USIM type, and rate plan type. Possible integrated dedicated network service can be provided. Accordingly, it is possible to reduce the network construction cost, and it is possible to conveniently operate heterogeneous core networks from a network operator's point of view.

In addition, the terminal is selectively connected between the LTE core network and the 5G core network according to the combination of the terminal type, USIM type, and rate plan type. Therefore, if the customer subscribes to only the enterprise-only 5G service, the customer's employees can select and connect to the appropriate core network according to the combination of the terminal type, USIM type, and rate plan type, so that the scalability of the service can be increased.

1 is a view for explaining a communication system according to an embodiment of the present invention.
2 is a flowchart illustrating a network access procedure according to an embodiment of the present invention.
3 is a flowchart illustrating a network access procedure according to another embodiment of the present invention.
4 is a flowchart illustrating a public network access process according to an embodiment of the present invention.
5 illustrates a public network access cancellation process according to network switching according to an embodiment of the present invention.
6 shows a dedicated network access process according to network switching according to an embodiment of the present invention.
7 is a flowchart illustrating a public network access process according to another embodiment of the present invention.
8 is a flowchart illustrating a public network access cancellation process according to network switching according to another embodiment of the present invention.
9 is a flowchart illustrating a public network access process according to an embodiment of the present invention.
10 is a flowchart illustrating a public network connection cancellation process according to network switching according to another embodiment of the present invention.
11 shows a dedicated network access process according to network switching according to another embodiment of the present invention.
12 is a flowchart illustrating a public network access process according to another embodiment of the present invention.
13 shows a public network connection cancellation process according to network switching according to another embodiment of the present invention.
14 shows a dedicated network access process according to network switching according to another embodiment of the present invention.
15 is a flowchart illustrating a public network access process according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated.

In addition, terms such as “…unit”, “…group”, “…module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. can

The devices described in the present invention are composed of hardware including at least one processor, a memory device, a communication device, and the like, and a program executed in combination with the hardware is stored in a designated place. The hardware has the configuration and capability to implement the method of the present invention. The program includes instructions for implementing the method of operation of the present invention described with reference to the drawings, and is combined with hardware such as a processor and a memory device to execute the present invention.

As used herein, “transmission or provision” may include not only direct transmission or provision, but also transmission or provision indirectly through another device or using a detour path.

In this specification, expressions described in the singular may be construed as singular or plural unless an explicit expression such as “a” or “single” is used.

In this specification, the same reference numbers refer to the same components regardless of the drawings, and "and/or" includes each and every combination of one or more of the referenced components.

In this specification, terms including an ordinal number such as first, second, etc. may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present disclosure, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

In this specification, a terminal is a generic concept meaning a user terminal in communication, and is a user equipment (UE), a mobile station (MS), a mobile terminal (MT), a subscriber station (SS), a portable subscriber station (PSS), and an AT ( Access Terminal), mobile station, mobile terminal, subscriber station, portable subscriber station, user equipment, access terminal, wireless device, etc. It may include all or part of the functions of a home country, a portable subscriber station, a user equipment, an access terminal, a wireless device, and the like.

The terminal is a base station (BS), an access point (Access Point, AP), a radio access station (RAS), a Node B (Node B), an advanced Node B (evolved NodeB, eNodeB), a transmission and reception base station ( It can be connected to a remote server by accessing a network device such as a Base Transceiver Station (BTS) or Mobile Multihop Relay (MMR)-BS.

The terminal includes various types of communication terminals such as mobile terminals such as smartphones, tablet terminals such as smart pads and tablet PCs, computers, and televisions.

Base Station (BS) is an Access Point (AP), Radio Access Station (RAS), Node B (Node B), Base Transceiver Station (BTS), MMR (Mobile Multihop Relay) )-BS, etc. may refer to, and may include all or some functions of an access point, a radio access station, a Node B, a transceiver base station, and an MMR-BS.

Embodiments of the present invention include 3rd Generation Partnership Project (3GPP) Long-Term Evolution (LTE), LTE-A, 3GPP2, Institute of Electrical and Electronics Engineers (IEEE) systems, FS_NextGen (Study on Architecture for Next Generation System), such as It may be supported by standard documents related to at least one of the 3GPP 5G systems. That is, steps or parts not described in order to clearly reveal the technical spirit of the present invention among the embodiments of the present invention may be supported by the document. In addition, all terms disclosed in this document may be described by the standard document.

According to an embodiment of the present invention, the communication system separates the public network and the private network through the core network, and allows only a specific region or a specific subscriber to access the private network. Here, the public network is a network that an unspecified number of people can access, and may also be referred to as a public network, a public network, or the Internet. A private network is a network in which external access is restricted for specific subscribers, and may also be referred to as a private network, a private network, or an intranet.

A service provided by a telecommunication service provider to corporate subscribers is defined as a dedicated corporate network service. A corporate subscriber refers to a subscriber who has agreed to or subscribed to use this private corporate network service. In this case, the dedicated network may be called an enterprise network.

The public network and the private network refer to separate traffic paths and do not necessarily have to be physically separated. For example, a public network and a private network may be different bearers created on the same physical path.

In the mobile communication environment of the present invention, a 4G LTE communication network and a 5G communication network are mixed. Accordingly, in the present invention, the core network may correspond to at least one of an LTE core network and a 5G core network.

LTE core network includes MME (Mobility Management Entity), SGW (Serving Gateway), PGW (Packet data network gateway), HSS (Home Subscriber Server), PCRF (Policy and Charging Control Function), etc., and is used in LTE communication system The concept of communication technology and network device configuration may be referred to in the embodiment of the present invention.

5G core network is AMF (Access and Mobility Function), SMF (Session Management Function), UPF (User Plane Function), UDM (User Data Management), UDR (Unified Data Repository), PCF (Policy Control Function), SPR (Subscriber) Profile Repository), and the like, communication technology used in the 5G communication system, and the concept of network device configurations may be referred to in an embodiment of the present invention.

In the embodiment of the present invention, the public network service is provided in each of the LTE core network and the 5G core network, but the dedicated network service is integrated into the 5G core network. This will be described with reference to the drawings.

1 is a view for explaining a communication system according to an embodiment of the present invention. In particular, it shows the network structure in which the LTE core network and the 5G core network are mixed.

Referring to FIG. 1 , the LTE UE 100 accesses the LTE core network 300 through an eNB (eNodeB) 201 . The LTE UE 101 refers to an LTE terminal using the LTE communication standard.

The 5G UE 103 connects to the LTE core network 300 through an eNB (eNodeB) 201 , and connects to the 5G core network 400 through a gNB (gNodeB) 203 . The 5G UE 103 refers to a 5G terminal using the 5G communication standard.

In this case, the 5G UE 103 connects to the eNB (eNodeB) 201 during radio signaling call processing, and transmits and receives user data through the gNB (gNodeB) 203 .

The eNB 201 is a base station used in an LTE system supporting interworking between LTE Radio technology and the LTE core network 300 . The gNB 203 is a new base station that is a next generation NodeB that supports New Radio technology and interworking with the 5G core network 400 .

In the communication system, the LTE core network 300 and the 5G core network 400 are mixed.

The LTE core network 300 includes an HSS 301 , an MME 303 , an SGW 305 , a PGW 307 and a PCRF 309 . In this case, the PGW 307 is connected to the public network 500 . That is, the LTE core network 300 is composed of core nodes for accessing the common network, that is, the public network 500 .

5G core network 400 is UDM / UDR (401), AMF (403), public SMF (405), dedicated SMF (407), public UPF (409), dedicated UPF (411), public PCF (413), dedicated PCF 415 , public SPR 417 , and dedicated SPR 419 . In this case, the 5G core network 400 includes a public core network for accessing the common DN 500 and a dedicated core network for accessing the dedicated network 600 . The common core network is composed of a common SMF (405), a common UPF (409), a common PCF (413), and a common SPR (417). 415), and a dedicated SPR (419).

The eNB 201 is connected to the MME 303 , the AMF 403 , the PGW 307 and the dedicated UPF 411 . gNB 203 is connected to AMF 403 , public UPF 409 and dedicated UPF 411 .

Basically, the LTE UE 101 uses an LTE Universal Subscriber Identity Module (USIM) and is subscribed to an LTE plan. The 5G UE 103 uses a 5G USIM and is subscribed to a 5G plan.

However, a user may be provided with a 5G service by equipping the LTE UE 101 with a 5G USIM. In addition, the LTE UE 101 may be subscribed to a 5G plan. Similarly, a user may be provided with an LTE service by equipping the 5G UE 103 with an LTE USIM. In addition, the 5G UE 103 may be subscribed to an LTE plan.

As such, the terminal type, USIM type, and rate plan type may be varied, and the core network selection criteria according to the combination for each type are shown in Table 1.

category terminal USIM rate plan Public LTE/5G Core Dedicated network 5G core ① 5G 5G 5G AMF SMF/UPF UDM/UDR eSMF/eUPF ② 5G 5G LTE AMF SGW PGW UDM/UDR eSMF/eUPF ③ 5G LTE 5G AMF SGW PGW AUC/HSS eSMF/eUPF ④ 5G LTE LTE AMF SGW PGW AUC/HSS eSMF/eUPF ⑤ LTE 5G 5G MME SGW PGW UDM/UDR eSMF/eUPF ⑥ LTE 5G LTE MME SGW PGW UDM/UDR eSMF/eUPF ⑦ LTE LTE 5G MME SGW PGW AUC/HSS eSMF/eUPF ⑧ LTE LTE LTE MME SGW PGW AUC/HSS eSMF/eUPF

As described above, since the LTE UE 101 and the 5G UE 103 connect to the eNB 201 during radio signaling call processing, the radio signaling call processing base station is the eNB 201 regardless of the terminal type, USIM type, and rate plan type. ), that is, an LTE base station.

Referring to Table 1, regardless of the terminal type, USIM type, or rate plan type, the dedicated network service is provided through the dedicated network 5G core node, that is, the dedicated (e, enterprise) SMF 407 and the dedicated UPF 411 .

The HSS 301 and the UDM/UDR 401 manage user subscription information and location information, respectively. User subscription information includes subscription data or a subscription record.

In particular, the HSS 301 includes an Authentication Center (AuC). The LTE key (K) and International Mobile Subscriber Identity (IMSI), which are master keys for EPS (Evolved Packet System), are stored in LTE USIM and AuC. Similarly, 5G master key and IMSI are stored in UDM/UDR 401 and 5G USIM in 5G.

The LTE key (K)/5G key and the IMSI are stored when the USIM card is manufactured, and the HSS 301 and the UDM/UDR 401 are provisioned when the user joins the operator network. In this case, the bands of the IMSI stored in the LTE USIM and the IMSI stored in the 5G USIM are different from each other.

Accordingly, subscriber authentication and information management for LTE USIM are performed by the HSS 301 . Subscriber authentication and information management for 5G USIM are performed by the UDR/UDM 401 .

The signaling call processing for the LTE UE 101 is performed by the MME 303 . The signaling call processing for the 5G UE 103 is performed by the AMF 403 .

When accessing the public network 500, the 5G UE 103 uses the 5G USIM The public SMF 405 and the public UPF 409 perform signaling call processing only when used and subscribed to a 5G plan. When accessing the public network 500, even the 5G UE 103 uses the LTE USIM or subscribes to the LTE plan, the SGW 305 and the PGW 307 perform signaling call processing.

When accessing the public network 500 or the private network 600, a core node is selected differently for each terminal type, USIM type, and rate plan type. The reference information for the selection of such a core node may be defined as a parameter as shown in Table 2.

ATTRIBUTE VALUE DESCRIPTION Network-Selection-Discriminator (NSD) 0 Attempt to connect to public network One Attempt to connect to private network Dedicated core-Selection-Discriminatotor (DSD) VALUE terminal USIM rate plan One 5G 5G 5G 2 5G 5G LTE 3 5G LTE 5G/LTE 4 LTE 5G 5G/LTE 5 LTE LTE 5G/LTE

In Table 2, Attribute is a parameter name, and VALUE is a value defined for each parameter. According to Table 2, the network classification information is composed of NSD and DSD. NSD is network selection indication information, and DSD is core selection indication information. NSD has a value of 0 or 1. DSD has one of 1, 2, 3, 4, and 5.

Such network identification information is stored in the HSS 301 and the UDM/UDR 401 . The integrated computer system 700 stores the network classification information of the LTE UE 101 in the HSS 301 at the time of terminal opening or subscription/change of the terminal's rate plan, and the network classification information of the 5G UE 103 is It is stored in UDM/UDR (401). In this case, the NSD is set to 0, which is a default value, and the DSD is set according to the terminal type, USIM type, and rate plan type.

The LTE UE 101 can switch networks from the public network 500 to the private network 600 and from the private network 600 to the public network 500, and the network switching request is made through the LTE network switching device 801. forwarded to the HSS 301 . Similarly, the 5G UE 103 may switch the network from the public network 500 to the private network 600 and from the private network 600 to the public network 500, and the network switching request is requested by the 5G network switching device 803. It is transmitted to the UDM / UDR (401) through. In this case, the NSD has a value of 0 or 1 according to a network switch request.

2 is a flowchart illustrating a network access procedure according to an embodiment of the present invention. In particular, it describes an operation after an MME receives a network access request. In this case, NSD has a value of 0 or 1 in Table 2, and DSD has one of 1, 2, 3, 4, and 5 in Table 2.

Referring to FIG. 2 , the HSS 301 and the UDM/UDR 401 set NSD and DSD for each IMSI of the terminals 101 and 103 based on the registration information received from the integrated computer system 700 ( S101 ). .

The MME 303 receives a network connection request (Attach Request) from the eNB 201 (S103). In this case, the network access request includes the IMSI of the terminals 101 and 103 .

The MME 303 determines whether the IMSI included in the network access request is an LTE IMSI band (eg, 4500860~) or a 5G IMSI band (4500800~) (S105). At this time, if it is determined that the MME 303 is the LTE IMSI band, it acquires NSD and DSD through the HSS 301 and network/terminal authentication. In addition, when it is determined that the MME 303 is a 5G IMSI band, it acquires NSD and DSD through the UDM/UDR 401 and network/terminal authentication.

If it is determined as the LTE IMSI band in step S105, the MME 303 performs an authentication procedure with the HSS 301 (S107). In this case, the LTE IMSI stored in the LTE USIM is used. When the authentication procedure (S107) is completed, the MME 303 transmits an Update Location Request to the HSS 301 (S109). The location update request includes the IMSI of the terminals 101 and 103 and the ID of the MME 303 . The HSS 301 transmits an Update Location Answer including the NSD and DSD set in the IMSI included in the location update request to the MME 303 (S111).

If it is determined as the 5G IMSI band in step S105, the MME 303 performs an authentication procedure with the UDM/UDR 401 (S113). In this case, the 5G IMSI stored in the 5G USIM is used. When the authentication procedure (S113) is completed, the MME 303 transmits a location update request to the UDM/UDR 401 (S115). The location update request includes the IMSI of the terminals 101 and 103 and the ID of the MME 303 . The UDM/UDR 401 transmits a location update response including the NSD and DSD set in the IMSI included in the location update request to the MME 303 (S117).

The MME 303 determines whether the NSD is 0 or 1 (S119). At this time, if it is determined as 1, the MME 303 determines that the access request in step S103 is a dedicated network access request and transmits a Create Session Request to the dedicated SMF 407 (S121). The session creation request is a data session creation request for access to the dedicated network 600 .

At this time, the MME 303 obtains the APN-OI Replacement from the location update response received in step S111 or step S117. The MME 303 transmits a session creation request to the dedicated SMF 407 matched to APN-OI Replacement (S121).

On the other hand, if the NSD is determined to be 0 in step S119, the MME 303 determines whether the DSD is one of 4 or 5 (S123). If the DSD is 4 or 5, the MME 303 transmits a session creation request to the SGW 305 (S125). In this case, the session creation request is a data session creation request for access to the public network 500 .

On the other hand, if the DSD is not 4 or 5, it is determined whether the DSD is one of 1, 2, and 3 (S127). If the DSD is one of 1, 2, and 3, the MME 303 transmits a Reroute message including the access request received in step S103 to the eNB 201 (S129).

3 is a flowchart illustrating a network access procedure according to another embodiment of the present invention. In particular, it describes an operation after the AMF receives a network access request. FIG. 3 may be a step performed after step S129 of FIG. 2 . In this case, NSD has a value of 0 or 1 in Table 2, and DSD has one of 1, 2, 3, 4, and 5 in Table 2.

Referring to FIG. 3 , the AMF 403 receives an access request from the eNB 201 ( S201 ). In the embodiment of the present invention, the radio signaling call transmitted from the terminals 101 and 103 is transferred to the eNB 201 .

The AMF 403 determines whether the IMSI band included in the access request received in step S201 is the LTE IMSI band or the 5G IMSI band (S203). If it is determined as the LTE IMSI band, the HSS 301, an authentication procedure (S205), and a location update procedure (S207, S209) are performed. In addition, if it is determined as the 5G IMSI band, the UDM/UDR 401, an authentication procedure (S205), and a location update procedure (S207, S209) are performed.

At this time, IMSI and AMF ID are transmitted in steps S207 and S213, and NSD and DSD are transmitted in steps S209 and S215.

The AMF 403 determines whether the NSD is 0 or 1 (S217). If it is determined as 1 in step S217, the SAMF 403 determines the access request in step S201 as a dedicated network access request. Then, a request for creating a dedicated data session for access to a dedicated network is transmitted to the dedicated SMF 407 (S219). At this time, the AMF 403 transmits a session creation request to the dedicated SMF 407 matching the APN-OI Replacement received in step S209 or S215 ( S219 ).

On the other hand, if it is determined as 0 in step S217, the AMF 403 determines the access request in step S201 as a public network access request. The AMF 403 determines whether the DSD is 1 (S221).

When the DSD is determined to be 1, the AMF 403 transmits a request for creating a public data session for access to the public network to the public SMF 405 (S223).

If the DSD is not 1, it is determined whether the DSD is 2 or 3 (S225). If the DSD is determined to be 2 or 3, the AMF 403 transmits a request for creating a public data session for access to the public network to the SGW 305 (S227).

In this way, based on the NSD and DSD, the public network access procedure and the dedicated network access procedure are performed differently. In addition, the NSD value (0) indicating access to the public network is set as a default, and is changed to 1 or 0 according to a network switch request from the terminals 101 and 103 . The DSD is set according to the terminal type, USIM type, and rate plan type, and accordingly, used core nodes are defined differently.

Hereinafter, a public network access process, a network switch process, and a dedicated network access process according to the combination of NSD and DSD will be described.

First, FIGS. 4, 5, and 6 are exemplary embodiments in which the DSD is 1. That is, it corresponds to the case of using a 5G UE 103 equipped with a 5G USIM and subscribing to a corporate 5G plan.

4 is a flowchart illustrating a public network access process according to an embodiment of the present invention.

Referring to FIG. 4 , the UDR/UDM 401 provisions subscriber information of the 5G UE 103 received from the integrated computer system 700 ( S301 ). At this time, since the subscriber information represents the 5G terminal/5G USIM/5G plan, NSD=0 (public network) and DSD=1 are set.

When the 5G UE 103 is powered on (S303), it connects to the eNB 201 and transmits an attach request (S305). The access request includes the IMSI configured in the 5G USIM of the 5G UE (103).

The eNB 201 transmits a connection request to the MME 303 (S307).

Since the IMSI band is a 5G band, the MME 303 inquires the subscriber information through the UDM/UDR 401 and the authentication procedure and the location update procedure, and through this, confirms that NSD=0, DSD=1 are set ( S309). Then, the MME 303 transmits a path change message including the access request received in step S307 to the eNB 201 (S311).

The eNB 201 transmits the access request included in the route change message to the AMF 403 (S313).

Since the IMSI band is the 5G band, the AMF 403 inquires the subscriber information through the UDM/UDR 401 and the authentication procedure and location update procedure, and through this, it confirms that NSD = 0 and DSD = 1 are set ( S315).

The AMF 403 selects the shared SMF 405 set in the APN-OI Replacement in the case of NSD=0 and DSD=1 (S317). The AMF 403 recognizes that the subscriber information parameter is NSD=0, so that it is a public network connection.

The AMF 403 transmits a session creation request for access to the public network to the public SMF 405 selected in step S317 (S319).

The common SMF 405 transmits a CCR-I (Credit Control Request-Initial) message to the common PCF 413 (S321).

The public PCF 413 transmits a Profile Request to the UDR/UDM 401 (S323) and receives a profile response including subscriber information (S325).

The common PCF 413 transmits a Credit Control Answer-Initial (CCA-I) message to the common SMF 405 (S327).

The public SMF 405 transmits a session establishment request to the public UPF 409 (S329).

The public UPF 409 transmits a session establishment response to the public SMF 405 (S331).

The public SMF 405 transmits a session creation response to the AMF 403 (S333).

The AMF 403 transmits an attachment response (Attach Accept) to the eNB 201 (S335). The eNB 201 transmits a connection response to the 5G UE 103 (S337).

Accordingly, the 5G UE 103 establishes an uplink traffic path in the public network 500 through a public data session (Public PDU Session) connected to the public UPF 409 through the eNB 201 .

5G UE 103 transmits an Attach Complete to the eNB 201 and the MME 303 (S339, S341).

MME 303 transmits a bearer modification request (Modify Bearer Request) to the public SMF (405) (S343).

The public SMF 405 transmits a session modification request to the public UPF 409 (S345). Then, the 5G UE 103 establishes a downlink traffic path in the public network 500 through a public data session (Public PDU Session) connected to the public UPF 409 through the eNB 201 .

At this time, the common UPF 409 transmits a session modification response to the common SMF 405 (S347). The public SMF (405) transmits a bearer modification response (Modify Bearer Response) to the MME (303) (S349).

Since the bearer generated by the access response of step S337 is guaranteed only for uplink traffic, it is also guaranteed for downlink traffic through the bearer modification procedure of S339 to S349.

In this case, the signaling data was delivered to the eNB 201 , but thereafter, uplink/downlink traffic may be delivered through the gNB 203 .

5 shows a public network access cancellation process according to network switching according to an embodiment of the present invention, which is performed after the process of FIG. 4 .

Referring to FIG. 4 , when a dedicated network access event occurs while the 5G UE 103 is connected in the public network 500 , a dedicated 5G trigger is transmitted to the 5G network switching device 803 ( S401 ). Here, the dedicated network access event may occur manually or automatically. For example, a dedicated 5G trigger may be transmitted when the user sets the dedicated network access app on, or a dedicated 5G trigger may be transmitted when entering a dedicated network service area.

The 5G network switching device 803 transmits a dedicated 5G trigger to the UDR/UDM 401 (S403).

The UDR/UDM 401 changes to NSD=1 according to the dedicated 5G trigger (S405). Accordingly, the parameters of subscriber information are set to NSD=1 and DSD=1.

The UDR/UDM 401 requests the AMF 403 to cancel the PDU Session of the public network in order to delete the public network session because the NSD value of the corresponding subscriber has been changed to '1' (NSD=1 means access to the corporate network). A Cancel Location message is transmitted (S407).

The AMF 403 transmits a Cancel location AcK message in response to the public network session termination to the UDR/UDM 401 (S409).

The AMF 403 transmits a connection termination request (Detach Request) to the 5G UE 103 (S411). In this case, the connection termination type of the connection termination request is set to a reconnection request (Detach Type=Reattach Required).

In addition, the AMF 403 transmits a session deletion request (Delete Session Request) to the public SMF 405 (S413). The public SMF 405 transmits a session deletion request to the public UPF 409 (S415) and receives a Delete Session Response (S417).

The public SMF 405 transmits a session deletion response to the AMF 403 (S419).

When the AMF 403 receives a connection release response (Detach Accept) from the 5G UE 103 (S421), the public network data session between the 5G UE 103 and the public UPF 409 is released.

6 shows a dedicated network access process according to network switching according to an embodiment of the present invention, which is performed after the process of FIG. 5 .

Referring to FIG. 6 , the 5G UE 103 transmits an access request to the eNB 201 ( S501 ). This access request is an access request caused by a reconnection trigger according to the release of a public network session.

The eNB 201 forwards the access request to the AMF 403 (S503).

The AMF 403 transmits a location update request to the UDR/UDM 401 (S505) and receives a location update response (S507).

The AMF 403 recognizes that the NSD = 1 obtained in step S507 is access to a dedicated network. Accordingly, a dedicated SMF 407 matching the subscriber information (NSD=1, DSD=1) is selected (S509).

The AMF 403 transmits a session creation request to the dedicated SMF 407 (S511).

The dedicated SMF 407 transmits a Radius Access Request to the dedicated SPR 419 (S513).

The dedicated SPR 419 performs authentication to determine whether the 5G UE 103 is a dedicated network subscriber (S515). The dedicated SPR 419 determines whether the 5G UE 103 is a static IP subscriber (S517).

If it is determined as a static IP subscriber, a static IP is allocated to the 5G UE 103 (S519). And if you are not a static IP subscriber, a static IP is not assigned.

The dedicated SPR 419 transmits a Radius Access Response to the dedicated SMF 407 (S521).

The dedicated SMF 407 determines whether the IP is included in the Radius connection response received in step S527 (S523), and if the static IP is not included, allocates a dynamic IP to the 5G UE 103 (S525).

The dedicated SMF 407 transmits a CCR-I message to the dedicated PCF 415 (S527).

The dedicated PCF 415 transmits a Spending Limit Notification Request (SNR) to the dedicated SPR 419 (S529) to receive a Spending Limit Notification Answer (SNA) (S531). The dedicated PCF 415 determines a policy to be applied to the 5G UE 103 via SNA.

The dedicated PCF 415 transmits the CCA-I message to the dedicated SMF 407 (S533).

The dedicated SMF 407 determines the QoS rules to be applied to the dedicated data session through the CCA-I message. The dedicated SMF 407 transmits a Session Establish Request requesting application of the determined QoS rule to the dedicated UPF 411 (S535).

The dedicated UPF 411 transmits a session establishment response to the dedicated SMF 407 (S537).

The dedicated SMF 407 transmits a session creation response to the AMF 403 (S539).

The AMF 403 transmits a connection response to the eNB 201 (S541). The eNB 201 transmits a connection response to the 5G UE 103 (S543).

At this time, after step S543, as described with reference to FIG. 4, the bearer modification procedure of S339 to S349 is performed. Accordingly, the 5G UE 103 establishes an uplink traffic path and a downlink traffic path in the dedicated network 600 through a private data session (Private PDU Session) connected to the dedicated UPF 411 through the eNB 201 . In this case, the signaling data was delivered to the eNB 201 , but thereafter, uplink/downlink traffic may be delivered through the gNB 203 .

Next, FIGS. 7 and 8 are examples in which the DSD is 2 . That is, it corresponds to the case of using a 5G UE 103 equipped with a 5G USIM and subscribing to an enterprise-only LTE plan.

7 is a flowchart illustrating a public network access process according to another embodiment of the present invention.

Referring to FIG. 7 , the UDR/UDM 401 provisions subscriber information of the 5G UE 103 received from the integrated computer system 700 ( S601 ). At this time, since the subscriber information indicates the 5G terminal/5G USIM/LTE plan, NSD=0 (public network) and DSD=2 are set.

When the 5G UE 103 is powered on (S603), it connects to the eNB 201 and transmits a connection request (S605). The access request includes the IMSI configured in the 5G USIM of the 5G UE (103).

The eNB 201 transmits a connection request to the MME 303 (S607).

Since the IMSI band is a 5G band, the MME 303 inquires the subscriber information through the UDM/UDR 401 and the authentication procedure and location update procedure, and through this, confirms that NSD=0, DSD=2 are set ( S609). Then, the MME 303 transmits a path change message including the access request received in step S607 to the eNB 201 (S611).

The eNB 201 transmits the access request included in the route change message to the AMF 403 (S613).

Since the IMSI band is a 5G band, the AMF 403 inquires the subscriber information through the UDM/UDR 401 and the authentication procedure and the location update procedure, and through this, it confirms that NSD=0, DSD=2 are set ( S615).

The AMF 403 selects the SGW 305 set in the APN-OI Replacement in the case of NSD=0 and DSD=2 (S617). The AMF 403 recognizes that the subscriber information parameter is NSD=0, so that it is a public network connection.

The AMF 403 transmits a session creation request for access to the public network to the SGW 305 selected in step S617 (S619). The SGW 305 transmits a session creation request to the PGW 307 (S621).

The PGW 307 transmits a CCR-I message to the common PCF 413 (S623). Here, since the PGW 307 is set to DSD=2, it transmits a CCR-I message to the common PCF 413 .

The public PCF 413 transmits a profile request to the UDR/UDM 401 (S625) and receives a profile response including subscriber information (S627).

The public PCF 413 transmits a CCA-I message to the PGW 307 (S629).

The PGW 307 transmits a session creation response to the SGW 305 (S631).

The SGW 305 transmits a session creation response to the AMF 403 (S633).

The AMF 403 transmits a connection response to the eNB 201 (S635). The eNB 201 transmits a connection response to the 5G UE 103 (S637).

Accordingly, the 5G UE 103 establishes an uplink traffic path in the public network 500 through the public data session connected to the SGW 305 and the PGW 307 through the eNB 201 . Thereafter, as described with reference to FIG. 4 , the bearer modification procedure of S339 to S349 is performed. That is, the 5G UE 103 exchanges a bearer modification message and a session modification message with the eNB 201 , the MME 303 , the SGW 305 , and the PGW 307 . Then, the 5G UE 103 establishes a downlink traffic path in the public network 500 through the public data session connected to the PGW 307 through the eNB 201 . At this time, the signaling data was delivered to the eNB 201 , but thereafter, uplink/downlink traffic may be delivered through the gNB 203 .

8 is a flowchart illustrating a public network access cancellation process according to network switching according to another embodiment of the present invention, which may be performed after step S637 of FIG. 7 .

Referring to FIG. 8 , when a dedicated network access event occurs while the 5G UE 103 is connected to the public network 500 , a dedicated 5G trigger is transmitted to the 5G network switching device 803 ( S701 ).

The 5G network switching device 803 transmits a dedicated 5G trigger to the UDR/UDM 401 (S703).

The UDR/UDM 401 changes to NSD=1 according to the dedicated 5G trigger (S705). Accordingly, the parameters of subscriber information are set to NSD=1 and DSD=2.

Since the NSD value of the corresponding subscriber has been changed to 1, the UDR/UDM 401 transmits a location cancellation message to the AMF 403 for requesting termination of the PDU Session of the public network to delete the public network session (S707).

The AMF 403 transmits a location cancellation response message in response to the public network session termination to the UDR/UDM 401 (S709).

The AMF 403 transmits a connection release request to the 5G UE 103 (S711).

The AMF 403 transmits a session deletion request to the SGW 305 (S713). The SGW 305 transmits a session deletion request to the PGW 307 (S715) and receives a session deletion response (S717).

The SGW 305 transmits a session deletion response to the AMF 403 (S719).

When the AMF 403 receives the connection release response from the 5G UE 103 (S721), the public network data session between the 5G UE 103 and the PGW 307 is released.

After step S721, the 5G UE 103 performs a procedure for accessing the dedicated network 600, which is the same as in FIG.

Next, FIGS. 9, 10, and 11 show an embodiment in which the DSD is 3 . That is, it corresponds to the case of using a 5G UE 103 equipped with an LTE USIM and subscribing to a 5G plan or LTE plan.

9 is a flowchart illustrating a public network access process according to an embodiment of the present invention.

Referring to FIG. 9 , the HSS 301 provisions subscriber information of the 5G UE 103 received from the integrated computer system 700 ( S801 ). In this case, since the subscriber information indicates a 5G terminal/LTE USIM/5G plan or LTE plan, NSD=0 (public network) and DSD=3 are set.

When the 5G UE 103 is powered on (S803), it connects to the eNB 201 and transmits a connection request (S805). The access request includes the IMSI configured in the LTE USIM of the 5G UE 103 .

The eNB 201 transmits a connection request to the MME 303 (S807).

Since the IMSI band is the LTE band, the MME 303 inquires the subscriber information through the HSS 301 and the authentication procedure and the location update procedure, and confirms that NSD = 0 and DSD = 3 are set through this (S809) . Then, the MME 303 transmits a path change message including the access request received in step S807 to the eNB 201 (S811).

The eNB 201 transmits the access request included in the route change message to the AMF 403 (S813).

Since the IMSI band is the LTE band, the AMF 403 inquires the subscriber information through the HSS 301 and the authentication procedure and location update procedure, and confirms that NSD = 0 and DSD = 3 are set through this (S815) .

The AMF 403 selects the SGW 305 set in the APN-OI Replacement in the case of NSD=0 and DSD=3 (S817). The AMF 403 recognizes that the subscriber information parameter is NSD=0, so that it is a public network connection.

The AMF 403 transmits a session creation request for public network access to the SGW 305 selected in step S817 (S819). The SGW 305 transmits a session creation request to the PGW 307 (S821).

The PGW 307 transmits a CCR-I message to the PCRF 309 (S823). Here, since the PGW 307 is set to DSD=3, it transmits a CCR-I message to the PCRF 309 .

The PCRF 309 transmits an SNR message to the public SPR 417 (S825) and receives the SNA message (S827). The PCRF 309 determines the policy based on the SNA message.

The PCRF 309 transmits a CCA-I message to the PGW 307 (S829). The PGW 307 determines the QoS rules to apply to the employment data session based on the CCA-I message.

The PGW 307 transmits a session creation response to the SGW 305 (S831).

The SGW 305 transmits a session creation response to the AMF 403 (S833).

The AMF 403 transmits a connection response to the eNB 201 (S835). The eNB 201 transmits a connection response to the 5G UE 103 (S837).

Accordingly, the 5G UE 103 establishes an uplink traffic path in the public network 500 through the public data session connected to the SGW 305 and the PGW 307 through the eNB 201 . Thereafter, as described with reference to FIG. 4 of FIG. 4 , the bearer modification procedure of S339 to S349 is performed. That is, the 5G UE 103 exchanges a bearer modification message and a session modification message with the eNB 201 , the MME 303 , the SGW 305 , and the PGW 307 . Then, the 5G UE 103 establishes a downlink traffic path in the public network 500 through the public data session connected to the PGW 307 through the eNB 201 . In this case, the signaling data was delivered to the eNB 201 , but thereafter, uplink/downlink traffic may be delivered through the gNB 203 .

10 is a flowchart illustrating a public network access cancellation process according to network switching according to another embodiment of the present invention, which may be performed after step S837 of FIG. 9 .

Referring to FIG. 10 , when a dedicated network access event occurs while the 5G UE 103 is connected to the public network 500 , a dedicated 5G trigger is transmitted to the 5G network switching device 803 ( S901 ).

The 5G network switching device 803 transmits a dedicated 5G trigger to the HSS 301 (S903).

The HSS 301 changes to NSD=1 according to the dedicated 5G trigger (S905). Accordingly, the parameters of subscriber information are set to NSD=1 and DSD=3.

Since the NSD value of the corresponding subscriber has been changed to 1, the HSS 301 transmits a location cancellation message requesting cancellation of the PDU Session of the public network to the AMF 403 in order to delete the public network session (S907).

The AMF 403 transmits a location cancellation response message in response to the public network session termination to the HSS 301 (S909).

The AMF 403 transmits a connection release request to the 5G UE 103 (S911).

The AMF 403 transmits a session deletion request to the SGW 305 (S913). The SGW 305 transmits a session deletion request to the PGW 307 (S915) and receives a session deletion response (S917).

The SGW 305 transmits a session deletion response to the AMF 403 (S919).

When the AMF 403 receives the connection release response from the 5G UE 103 (S921), the public network data session between the 5G UE 103 and the PGW 307 is released.

11 shows a dedicated network access process according to network switching according to another embodiment of the present invention, which is performed after the process of FIG. 10 .

Referring to FIG. 11 , since it is almost similar to FIG. 6 , a description of overlapping steps is omitted, and only steps different from those of FIG. 6 will be described.

Here, S1001 to S1003 are the same as S501 to S503 of FIG. 6 . S1013 to S1043 are the same as S513 to S543.

However, unlike FIG. 6 , the AMF 403 requests a location update from the HSS 301 after step S1003 ( S1005 ) and receives a location update response including NSD and DSD ( S1007 ).

The AMF 403 selects the dedicated SMF 407 matching the subscriber information (NSD=1, DSD=3) received in step S1007 and requests for session creation (S1011).

Next, FIGS. 12, 13 and 14 show an embodiment in which the DSD is 4 . That is, it corresponds to the case of using the LTE UE 101 equipped with 5G USIM and subscribing to the 5G plan or LTE plan.

12 is a flowchart illustrating a public network access process according to another embodiment of the present invention.

Referring to FIG. 12 , the UDR/UDM 401 provisions subscriber information of the 5G UE 103 received from the integrated computer system 700 ( S1101 ). At this time, since the subscriber information indicates an LTE terminal/5G USIM/5G plan or an LTE plan, NSD=0 (public network) and DSD=4 are set.

When the LTE UE 101 is powered on (S1103), it connects to the eNB 201 and transmits a connection request (S1105). The access request includes the IMSI configured in the 5G USIM of the LTE UE 101 .

The eNB 201 transmits a connection request to the MME 303 (S1107).

Since the IMSI band is a 5G band, the MME 303 inquires the subscriber information through the UDM/UDR 401 and the authentication procedure and location update procedure, and through this, confirms that NSD=0, DSD=4 are set ( S1109). Then, the MME 303 selects the SGW 305 set in the APN-OI Replacement in the case of NSD=0 and DSD=4 (S1111). Since the parameter of subscriber information is NSD=0, the MME 303 recognizes that it is a public network connection.

The MME 303 transmits a session creation request for public network access to the SGW 305 selected in step S1111 (S1113). The SGW 305 transmits a session creation request to the PGW 307 (S1115).

The PGW 307 transmits a CCR-I message to the common PCF 413 (S1117). Here, since the PGW 307 is set to DSD=4, it transmits a CCR-I message to the common PCF 413 .

The public PCF 413 transmits a profile request to the UDR/UDM 401 (S1119) and receives a profile response including subscriber information (S1121).

The common PCF 413 transmits a CCA-I message to the PGW 307 (S1123).

The PGW 307 transmits a session creation response to the SGW 305 (S1125).

The SGW 305 transmits a session creation response to the MME 303 (S1127).

The MME 303 transmits a connection response to the eNB 201 (S1129). The eNB 201 transmits a connection response to the 5G UE 103 (S1131).

As a result, the LTE UE 101 establishes an uplink traffic path in the public network 500 through the public data session connected to the SGW 305 and the PGW 307 through the eNB 201 . Thereafter, as described with reference to FIG. 4 , the bearer modification procedure of S339 to S349 is performed. That is, the LTE UE 101 exchanges a bearer modification message and a session modification message with the eNB 201 , the MME 303 , the SGW 305 , and the PGW 307 . Then, the LTE UE 101 establishes a downlink traffic path in the public network 500 through the public data session connected to the PGW 307 through the eNB 201 .

13 shows a public network access cancellation process according to network switching according to another embodiment of the present invention, which is performed after the process of FIG. 12 .

Referring to FIG. 13 , when a dedicated network access event occurs while the LTE UE 103 is connected to the public network 500 , a dedicated LTE trigger is transmitted to the LTE network switching device 801 ( S1201 ).

The LTE network switching device 801 transmits a dedicated LTE trigger to the UDR/UDM 401 (S1203).

The UDR/UDM 401 changes to NSD=1 according to the dedicated LTE trigger (S1205). Accordingly, the parameters of subscriber information are set to NSD=1 and DSD=4.

Since the NSD value of the corresponding subscriber is changed to 1, the UDR/UDM 401 transmits a location cancellation message requesting termination of the PDU Session of the public network to the MME 303 in order to delete the public network session (S1207). At this time, since the MME 303 is registered in the UDR/UDM 401 through the location update procedure as in step S115 of FIG. 2 , a location cancellation message is transmitted to the MME 303 .

The MME 303 transmits a location cancellation response message in response to the public network session termination to the UDR/UDM 401 (S1209).

The MME 303 transmits a connection release request to the LTE UE 101 (S1211).

The MME 303 transmits a session deletion request to the SGW 305 (S1213). The SGW 305 transmits a session deletion request to the PGW 307 (S1215) and receives a session deletion response (S1217).

The SGW 305 transmits a session deletion response to the MME 303 (S1219).

When the MME 303 receives the connection release response from the 5G UE 103 (S1221), the public network data session between the LTE UE 101 and the PGW 307 is released.

14 shows a dedicated network access process according to network switching according to another embodiment of the present invention, which is performed after the process of FIG. 13 .

Referring to FIG. 14 , the LTE UE 101 transmits an access request to the eNB 201 ( S1301 ). This access request is an access request caused by a reconnection trigger according to the release of a public network session.

The eNB 201 forwards the access request to the MME 303 (S1303). Since the MME 303 is a 5G IMSI, it acquires subscriber information (NSD, DSD) by interworking with the UDM/UDR 401 (S1305).

Since the MME 03 is NSD=1 and DSD=4, it transmits a location update request to the UDR/UDM 401 (S1207) and receives a location update response (S1309).

Since the MME 03 is NSD=1, it recognizes that it is a dedicated network connection. Accordingly, a dedicated SMF 407 matching the subscriber information (NSD=1, DSD=4) is selected (S1311).

The MME 03 transmits a session creation request to the dedicated SMF 407 (S1313).

The dedicated SMF 407 transmits a Radius connection request to the dedicated SPR 419 (S1315).

The dedicated SPR 419 performs authentication to determine whether the LTE UE 101 is a dedicated network subscriber (S1217). The dedicated SPR 419 determines whether the LTE UE 101 is a static IP subscriber (S1319).

If it is determined as a static IP subscriber, a static IP is allocated to the LTE UE 101 (S1321). And if you are not a static IP subscriber, a static IP is not assigned.

The dedicated SPR 419 transmits a radio connection response to the dedicated SMF 407 (S1323).

The dedicated SMF 407 determines whether the IP is included in the Radius connection response received in step S1323 (S1325), and if the static IP is not included, allocates a dynamic IP to the LTE UE 101 (S1327).

The dedicated SMF 407 transmits a CCR-I message to the dedicated PCF 415 (S1329).

The dedicated PCF 415 transmits the SNR to the dedicated SPR 419 (S1231) to receive the SNA (S1333). The dedicated PCF 415 determines a policy to be applied to the LTE UE 101 via SNA.

The dedicated PCF 415 transmits a CCA-I message to the dedicated SMF 407 (S1335).

The dedicated SMF 407 determines the QoS rules to be applied to the dedicated data session through the CCA-I message. The dedicated SMF 407 transmits a session establishment request requesting application of the determined QoS rule to the dedicated UPF 411 (S1337).

The dedicated UPF 411 transmits a session establishment response to the dedicated SMF 407 (S1339).

The dedicated SMF 407 transmits a session creation response to the AMF 403 (S1341).

The AMF 403 transmits a connection response to the eNB 201 (S1343). The eNB 201 transmits a connection response to the LTE UE 101 (S1345).

At this time, after step S1345, as described with reference to FIG. 4, the bearer modification procedure of S339 to S349 is performed. Accordingly, the LTE UE 101 establishes an uplink traffic path and a downlink traffic path in the dedicated network 600 through a dedicated data session connected to the dedicated UPF 411 through the eNB 201 .

Finally, FIGS. 15 and 16 are examples in which the DSD is 5. As shown in FIG. That is, it corresponds to the case of using an LTE UE 101 equipped with an LTE USIM and subscribing to a 5G plan or an LTE plan.

15 is a flowchart illustrating a public network access process according to another embodiment of the present invention.

Referring to FIG. 15 , the HSS 301 provisions subscriber information of the LTE UE 101 received from the integrated computer system 700 ( S1401 ). At this time, since the subscriber information indicates an LTE terminal/LTE USIM/5G plan or an LTE plan, NSD=0 (public network) and DSD=5 are set.

When the LTE UE 101 is powered on (S1403), it connects to the eNB 201 and transmits a connection request (S1405). The access request includes the IMSI configured in the LTE USIM of the LTE UE 101 .

The eNB 201 transmits a connection request to the MME 303 (S1407).

Since the IMSI band is the LTE band, the MME 303 inquires the subscriber information through the HSS 301 and the authentication procedure and location update procedure, and confirms that NSD = 0 and DSD = 5 are set through this (S1409) .

The MME 303 selects the SGW 305 set in the APN-OI Replacement in the case of NSD=0 and DSD=5 (S1411). Since the parameter of subscriber information is NSD=0, the MME 303 recognizes that it is a public network connection.

The MME 303 transmits a session creation request for public network access to the SGW 305 selected in step S1411 (S1413). The SGW 305 transmits a session creation request to the PGW 307 (S1415).

The PGW 307 transmits a CCR-I message to the PCRF 309 (S1417). Here, since the PGW 307 is set to DSD=5, it transmits a CCR-I message to the PCRF 309 .

The PCRF 309 transmits an SNR message to the public SPR 417 (S1419) and receives the SNA message (S1421). The PCRF 309 determines the policy based on the SNA message.

The PCRF 309 transmits a CCA-I message to the PGW 307 (S1423). The PGW 307 determines a QoS rule to apply to the public data session based on the CCA-I message.

The PGW 307 transmits a session creation response to the SGW 305 (S1425).

The SGW 305 transmits a session creation response to the MME 303 (S1427).

The MME 303 transmits a connection response to the eNB 201 (S1429). The eNB 201 transmits a connection response to the LTE UE 101 (S1431).

As a result, the LTE UE 101 establishes an uplink traffic path in the public network 500 through the public data session connected to the SGW 305 and the PGW 307 through the eNB 201 . Thereafter, as described with reference to FIG. 4 , the bearer modification procedure of S339 to S349 is performed. That is, the LTE UE 103 exchanges a bearer modification message and a session modification message with the eNB 201 , the MME 303 , the SGW 305 , and the PGW 307 . Then, the LTE UE 103 establishes a downlink traffic path in the public network 500 through the public data session connected to the PGW 307 through the eNB 201 .

After step S1431, the public network connection cancellation process according to the network switch of the LTE UE 101 is the same as in FIG. 13 . However, the difference is that since DSD=5, the HSS 301 is used as the subscriber device, not the UDM/UDR 401 .

In addition, after disconnection from the public network, the LTE UE 101 performs a procedure for accessing the dedicated network 600 in the same manner as in FIG. 14 . In this case, as well, since DSD = 5, the procedure is the same except that the HSS 301, not the UDM/UDR 401, is used as the subscriber device.

The embodiment of the present invention described above is not implemented only through the apparatus and method, and may be implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention or a recording medium in which the program is recorded.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improved forms of the present invention are also provided by those skilled in the art using the basic concept of the present invention as defined in the following claims. is within the scope of the right.

Claims (14)

As a method of operation of a Mobility Management Entity (MME),
receiving, by the MME, the access request of the terminal from the base station;
Receiving core selection indication information and network selection indication information of the terminal from the subscriber device;
determining the access request as a private network access request or a public network access request based on the network selection indication information;
If the access request is determined as a dedicated network access request, transmitting the dedicated network access request to a 5G dedicated core network;
If the access request is determined to be a public network access request, determining whether the core network through which the public network access request is transmitted is a Long-Term Evolution (LTE) common core network or a 5G common core network based on the core selection indication information , and
transmitting the public network access request to the LTE common core network or the 5G common core network according to the determination
Including, the method of operation of the MME. In claim 1,
The core selection indication information is,
It consists of a combination of the terminal type, the terminal's USIM (Universal Subscriber Identity Module) type, and the terminal's plan type,
The terminal type indicates whether the terminal is an LTE terminal or a 5G terminal,
The USIM type indicates whether the USIM mounted on the terminal is an LTE USIM or a 5G USIM,
The method of operation of the MME, wherein the rate plan type indicates whether the rate plan of the terminal is an LTE plan or a 5G plan. In claim 2,
The delivering step is
When the core network to which the public network access request is transmitted is determined as the 5G common core network based on the core selection indication information, a re-route message including the public network access request is transmitted to the AMF of the 5G common core network. (Access and Mobility Management Function), and
When the core network through which the public network access request is transmitted is determined as the LTE common core network based on the core selection indication information, the public network accesses to a Serving Gateway (SGW) to which a Packet Data Network Gateway (PGW) of the LTE common core network is connected. Sending a request to create a public data session for
Further comprising, the method of operation of the MME. In claim 3,
Between receiving the connection request and receiving the network selection indication information,
Further comprising the step of determining whether the terminal uses an LTE Universal Subscriber Identify Module (USIM) or a 5G USIM based on the band of the International Mobile Subscriber Identity (IMSI) included in the access request,
Receiving the network selection indication information comprises:
Receive network selection indication information and the core selection indication information of a terminal using LTE USIM from Home Subscriber Server (HSS), or network selection indication information and the core of a terminal using 5G USIM from UDM (Unified Data Management) Receiving selection indication information, an operating method of the MME. As a method of operation of a Mobility Management Entity (MME),
MME receiving the access request of the terminal from the base station,
Receiving network selection indication information and core selection indication information of the terminal from the subscriber device;
determining whether the access request is a public network access request or a private network access request based on the network selection indication information;
If the access request is a dedicated network access request, determining a dedicated SMF (Session Management Function) and a dedicated UPF (User Plane Function) as a core node to connect the terminal and a dedicated data session; and
If the access request is a public network access request, determining a core node to connect the terminal and the public network data session based on the core selection indication information
Including, the method of operation of the MME. In claim 5,
The step of determining a core node to which the public network data session will be connected includes:
When the core selection indication information indicates an LTE terminal, determining a Serving Gateway (SGW) and a Packet Data Network Gateway (PGW) as a core node to which the public network data session will be connected, an operation method of an MME. In claim 5,
The step of determining a core node to which the public network data session will be connected includes:
When the core selection indication information indicates a 5G terminal, transmitting a re-route message including the access request to the base station,
The access request included in the route change message is,
It is transmitted from the base station to AMF (Access and Mobility Management Function),
The public network data session is
Connected between the terminal and the core node determined by the AMF, the operating method of the MME. In claim 7,
The core node to connect the public network data session is,
When the core selection indication information indicates a 5G terminal that uses a 5G Universal Subscriber Identify Module (USIM) and subscribes to a 5G plan, it is determined as a public SMF and a public UPF, the method of operating the MME. In claim 8,
The core node to connect the public network data session is,
When the core selection indication information indicates a 5G terminal that uses an LTE USIM or subscribes to an LTE plan, it is determined as a Serving Gateway (SGW) and a Packet Data Network Gateway (PGW). A method of operating an Access and Mobility Management Function (AMF), comprising:
AMF receiving the access request of the terminal from the base station,
Receiving network selection indication information of the terminal from the subscriber device;
determining the access request as a public network access request based on the network selection indication information; and
requesting a public Session Management Function (SMF) associated with the public UPF to create a public data session;
The public network access request is
The method of operation of the AMF, which is included in the re-route message transmitted by the Mobility Management Entity (MME) to the base station. In claim 10,
After receiving the network selection indication information,
determining the access request as a dedicated network access request based on the network selection indication information; and
Step of requesting creation of a dedicated data session from a dedicated Session Management Function (SMF) connected to a dedicated UPF (User Plane Function)
Further comprising, the method of operation of the AMF. In claim 11,
Receiving the network selection indication information, further receiving core selection indication information,
The request to create the public data session is
When the core selection indication information indicates a 5G terminal that uses a 5G Universal Subscriber Identity Module (USIM) and subscribes to a 5G plan, it is transmitted to the public SMF. In claim 12,
After determining the public network access request,
When the core selection indication information indicates a terminal that does not use a 5G USIM or a 5G terminal that is not a 5G plan, the method further comprising the step of requesting the creation of a public data session from a Serving Gateway (SGW);
The public data session is
A method of operating an AMF, established by the SGW between a Packet Data Network Gateway (PGW) and the 5G terminal and used for data transfer between a public network connected to the PGW and the 5G terminal. In claim 13,
The base station that has transmitted the route change message to the AMF is an eNB (eNodeB),
The common UPF or the dedicated UPF is,
A method of operating an AMF for transmitting and receiving data to and from the terminal through a gNB (gNodeB).

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