KR102295738B1 - Base station and control method thereof - Google Patents

Abstract

The present invention realizes a new technology (method) which pre-separates traffic to an edge node (MEC) in an ultra-edge environment to selectively transmit only traffic required for determining whether to provide an analysis-based edge service to the edge node (MEC).

Description

BASE STATION AND CONTROL METHOD THEREOF

The present invention relates to an edge service provided between a base station and a core network, and more particularly, to a technology for pre-separating and delivering traffic to an edge node.

Edge nodes (e.g., MEC, mobile edge computing) located between the base station and the core network, in particular, the edge nodes (MEC) positioned very close to the base station, for traffic targeted for edge service of the base station, nodes in the core network (e.g. SGW) Instead of routing to (serving gateway) or UPF (user plane function), it provides edge services that are processed locally.

Briefly explaining this edge service, the edge node (MEC) recognizes data traffic (uplink packet) delivered from the base station to an application (eg, Local Breakout application, LBO app) installed on the edge node (MEC), Instead of forwarding to a node in the core network (eg, SGW or UPF, etc.), it is forwarded to a local (eg, local application) so that it is processed locally.

At this time, for the base station, it is determined that the traffic it transmits is being communicated with the application server through the node (eg, SGW or UPF, etc.) in the core network, and the node IP (eg, SGW IP, or UPF IP) and GTP GTP protocol packets destined for Tunnel Endpoint ID (TEID) are generated and transmitted over the uplink.

The edge node (MEC) analyzes the application packet encapsulated in the GTP packet of the uplink (eg, in the case of having a preset LBO app IP as the destination IP, etc.), and this time uplink packet It is determined whether the traffic is for the edge service provision target, and uplink packets determined as the edge service provision target traffic are branched/delivered to be processed locally (eg, LBO app).

In this way, in the ultra-edge environment where the edge node (MEC) is located in close proximity to the base station, all traffic from the base station is set to be delivered to the edge node (MEC), and the edge node (MEC) targets all the traffic and provides analysis-based A method of determining whether edge service is provided/branching to local is implemented.

Accordingly, according to the above-described edge service implementation, there are problems such as capacity increase for traffic analysis/local branching at the edge node (MEC), and user packet delay and performance (throughput) limitations due to large-capacity traffic analysis. .

Therefore, in the present invention, by realizing a method of pre-separating traffic to the edge node (MEC) and delivering only the traffic that requires analysis-based edge service determination to be delivered to the edge node (MEC), We want to improve the problems that arise in the implementation.

The present invention was created in consideration of the above circumstances, and by pre-separating traffic to the edge node (MEC) in an ultra-edge environment, only traffic requiring analysis-based edge service determination is selectively sent to the edge node (MEC). It's about realizing a way to deliver it.

According to a first aspect of the present invention, there is provided a base station apparatus, comprising: a data receiving unit for receiving uplink data from a terminal; And by differentiating the delivery path to the core network for the specific uplink data and the remaining uplink data for which edge service determination is required among the uplink data, the specific uplink data is locally branched instead of the core network to provide an edge service It includes a path control unit to be transmitted to the edge node to determine whether to provide.

Specifically, for each terminal, a factor for an edge service is allocated to a communication path that is connected to a basic or additional connection according to at least one of terminal subscriber information and an operation of using the edge service application; The specific uplink data may be uplink data received through a communication path to which the edge service factor is assigned.

Specifically, the factor for edge service is a Slice ID allocated to a basic session according to terminal subscriber information, or UE Usage Type (UUT), or Service Profile Identifier (SPID), or an additional session according to a usage operation of an edge service application. Alternatively, it may be defined as a Slice ID allocated to an additional bearer, or an Access Point Name (APN), or a 5G QoS Indicator (5QI), or a QoS Class Identifier (QCI).

Specifically, the path-related node involved in the forwarding path for transmitting uplink data to the core network is related to the first path-related node that induces a forwarding path without the edge node and the second path-related node that induces the forwarding path through the edge node. It operates differently as a node; The path control unit may set a path-related node used when transmitting the specific uplink data to the core network as a specific second path-related node defined in an edge service factor of a communication path through which the specific uplink data is received. .

Specifically, the path-related node may include at least one of a virtual LAN (VLAN) and a default gateway.

Specifically, the IP pool for the uplink endpoint (UL Endpoint) node in the core network that is allocated to the uplink data is defined for the forwarding path without the edge node, and the delivery via the edge node differently defined as a second IP pool defined for routes; The path control unit, when delivering the specific uplink data to the core network, performs an uplink for the specific uplink data within a specific second IP pool defined in the factor for edge service of the communication path through which the specific uplink data is received. It is possible to allocate an IP for a link endpoint (UL Endpoint) node.

A method of operating a base station apparatus according to a second aspect of the present invention for achieving the above object includes: a data receiving step of receiving uplink data from a terminal; And by differentiating the delivery path to the core network for the specific uplink data and the remaining uplink data for which edge service determination is required among the uplink data, the specific uplink data is locally branched instead of the core network to provide an edge service It includes a path control step to be delivered to the edge node to determine whether to provide.

Specifically, for each terminal, a factor for an edge service is allocated to a communication path that is connected to a basic or additional connection according to at least one of terminal subscriber information and an operation of using the edge service application; The specific uplink data may be uplink data received through a communication path to which the edge service factor is assigned.

Specifically, the path-related node involved in the forwarding path for transmitting uplink data to the core network is related to the first path-related node that induces a forwarding path without the edge node and the second path-related node that induces the forwarding path through the edge node. It operates differently as a node; In the path control step, a path-related node used when transmitting the specific uplink data to the core network may be set as a specific second path-related node defined in an edge service factor of a communication path through which the specific uplink data is received. have.

Specifically, the path-related node may include at least one of a virtual LAN (VLAN) and a default gateway.

Specifically, the IP pool for the uplink endpoint (UL Endpoint) node in the core network that is allocated to the uplink data is defined for the forwarding path without the edge node, and the delivery via the edge node differently defined as a second IP pool defined for routes; In the path control step, when the specific uplink data is transmitted to the core network, the specific uplink data is applied to the specific uplink data within a specific second IP pool defined in the factor for edge service of the communication path through which the specific uplink data is received. It is possible to allocate an IP for an uplink endpoint (UL Endpoint) node.

Therefore, according to the base station apparatus and the operating method of the base station apparatus according to the present invention, traffic to the edge node (MEC) is pre-separated in the ultra-edge environment, and only the traffic requiring analysis-based edge service determination is selectively performed on the edge node. (MEC) can be realized.

For this reason, according to the present invention, various problems caused by the transmission of all traffic from the base station to the edge node (MEC) can be improved, and the effect of improving the efficiency and service stability of the edge service is derived.

1 is a conceptual diagram showing a traffic delivery path of an existing edge service.
2 is a conceptual diagram illustrating a traffic delivery path of an edge service to which the method of the present invention is applied.
3 is a block diagram showing the configuration of a base station apparatus according to an embodiment of the present invention.
4 is an operation flowchart illustrating a method of operating a base station apparatus according to an embodiment of the present invention.

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

Edge nodes (e.g., MEC, mobile edge computing) located between the base station and the core network, in particular, the edge nodes (MEC) positioned very close to the base station, for traffic targeted for edge service of the base station, nodes in the core network (e.g. SGW) Instead of routing to (serving gateway) or UPF (user plane function), it provides edge services that are processed locally.

Briefly explaining this edge service, the edge node (MEC) recognizes data traffic (uplink packet) delivered from the base station to an application (eg, Local Breakout application, LBO app) installed on the edge node (MEC), Instead of forwarding to a node in the core network (eg, SGW or UPF, etc.), it is forwarded to a local (eg, local application) so that it is processed locally.

In this regard, FIG. 1 shows a traffic delivery path of an existing edge service.

As shown in FIG. 1 , the base station 10 determines that the traffic it transmits is being communicated with the application server through a node (eg, SGW or UPF, etc.) in the core network, and the node IP (eg: SGW IP, or UPF IP) and GTP Tunnel Endpoint ID (TEID) as destinations are generated and transmitted to the uplink.

In the edge node (MEC or MEC system, 20), an analysis of the application packet encapsulated in the GTP packet of the uplink (eg, a case of having a preset LBO app IP as the destination IP, etc.) is performed. , determines whether this uplink packet is the edge service provision target traffic, branches/delivers the uplink packets determined to be edge service provision target traffic to be processed locally (e.g., LBO app), and edge service provision target The uplink packets that are determined not to be traffic of the core network are delivered to the node (30, SGW or UPF, etc.) in the core network.

As such, in a super edge environment in which the edge node 20 is located in close proximity to the base station, all traffic from the base station 10 is set to be delivered to the edge node 20, and the edge node 20 targets all the traffic. A method of determining whether an edge service is provided based on analysis/branching to local is implemented.

On the other hand, it is common that terminals not subscribed to the edge service (hereinafter referred to as 1) and terminals subscribed to the edge service (hereinafter referred to as 2) are mixed. A situation in which traffic (hereinafter, LBO app traffic) and general Internet traffic are mixed is common.

According to the above-described edge service implementation in such a mixed situation, since all traffic from the base station 10 is set to be delivered to the edge node 20, the edge node 20 analyzes traffic at the edge node (MEC) / local branch In addition to the problem of capacity increase for high-capacity traffic, problems such as user packet delay and performance (throughput) limitations occur due to the analysis of large-capacity traffic because it is necessary to analyze all of the large-capacity traffic.

Therefore, in the present invention, by pre-separating traffic to an edge node (MEC or MEC system), only the traffic that requires analysis-based edge service provision determination is selectively delivered to the edge node. We want to improve the problems that occur in the implementation of the existing method.

2 shows a traffic delivery path of an edge service to which the method of the present invention is applied.

That is, as shown in FIG. 2 , in the present invention, the method is to transfer all base station traffic to the edge node (MEC, or MEC system) in an ultra-edge environment in which an edge node (MEC, or MEC system) is located in close proximity to a base station. Unlike the existing implementation of first delivery, only this traffic (e.g., LBO app traffic of the terminal 2) is delivered to the edge node (MEC or MEC system) by pre-separating the traffic that requires analysis-based edge service determination. and the remaining traffic (e.g., traffic of terminal 1, Internet traffic of terminal 2) goes to a node (30, SGW or UPF, etc.) in the core network without going through an edge node (MEC or MEC system). way to get it delivered.

As such, the method realized/proposed in the present invention should be implemented at the front end of the edge node (MEC, or MEC system), and according to an embodiment may be implemented at the base station 100 end as shown in FIG. 2 .

In FIG. 2 , one base station 100 is illustrated for convenience of description, but there may be a plurality of base stations transmitting traffic to an edge node (MEC or MEC system).

On the other hand, signaling between the terminal, the base station, and the core network is performed according to the 3GPP standard procedure, and the implementation of the method of the present invention on a non-standard basis or changing the 3GPP standard itself into a form that is easy to realize the method of the present invention is existing/current. It will be difficult to commercialize in a telecommunication environment.

Therefore, in the present invention, while maintaining and following the signaling between entities according to the 3GPP standard procedure without change, traffic to the edge node (MEC, or MEC system) is pre-separated, and only the traffic that requires analysis-based edge service determination We want to realize a way to selectively deliver to edge nodes.

Hereinafter, with reference to FIG. 3, the configuration of a base station apparatus for realizing the method proposed by the present invention will be described in detail.

The base station apparatus 100 according to an embodiment of the present invention may include a data receiving unit 110 and a path control unit 120 .

All or at least part of the configuration of the base station apparatus 100 of the present invention may be implemented in the form of a hardware module or a software module, or may be implemented in a form in which a hardware module and a software module are combined.

Here, the software module may be understood as, for example, instructions executed by a processor that controls operations in the base station apparatus 100, and these instructions may have a form mounted in a memory in the base station apparatus 100. .

As a result, the base station apparatus 100 according to an embodiment of the present invention realizes a new method proposed by the present invention, that is, a traffic line separation/delivery method to an edge node, through the above-described configuration. Each configuration in the base station apparatus 100 will be described in more detail.

The data receiving unit 110 is responsible for receiving uplink data from the terminal.

That is, the data receiving unit 110 receives uplink data ( uplink packets).

Accordingly, the uplink data (uplink packet) received through the data receiving unit 110 may be Internet traffic of the terminal 1 , LBO app traffic of the terminal 2 or general Internet traffic.

The path control unit 120 varies the transmission path to the core network for the specific uplink data that is required to determine whether edge service is provided among the uplink data received through the data receiving unit 110 and the remaining uplink data. It is responsible for the function of sending uplink data to the edge node (MEC, or MEC system, 20) that determines whether to provide edge service by branching locally instead of the node (30, SGW or UPF, etc.) in the core network. .

That is, the path control unit 120 controls the traffic (specific uplink data) and the remaining traffic (remaining uplink data) for which analysis-based edge service determination is required among the uplink data received through the data receiving unit 110 . By changing the forwarding path to the core network, only the traffic of specific uplink data (eg, LBO app traffic of the terminal 2) can be delivered to the edge node 20, and the traffic of the remaining uplink data (eg, LBO app traffic) : The traffic of the terminal 1, the Internet traffic of the terminal 2) are transmitted to the node 30, SGW or UPF, etc. in the core network without passing through the edge node 20.

To this end, in the base station apparatus 100 of the present invention, in particular, the path control unit 120, the traffic (specific uplink data) to the edge node 20 among the uplink data received through the data receiving unit 110 is pre-separated. It is required to realize the function and to set the forwarding path differently so that only pre-separated traffic (specific uplink data) is transmitted to the edge node 20 .

In particular, as described above, in the present invention, while maintaining and following signaling between entities according to the 3GPP standard procedure without change, the above function is to be realized.

First, the realization of the function of pre-separating traffic (specific uplink data) will be described in detail below.

In the present invention, it is premised on an environment in which an edge service factor is allocated to a communication path connected to a basic or additional connection according to at least one of terminal subscriber information and an operation of using an edge service application for each terminal.

In this case, specific uplink data corresponding to traffic to the edge node 20 may be defined as uplink data received through a communication path (eg, session, bearer) to which the above-described edge service factor is assigned. .

Here, the edge service factor may be defined as a Slice ID allocated to a basic session according to terminal subscriber information, a UE Usage Type (UUT), or a Service Profile Identifier (SPID).

Or, the factor for edge service is Slice ID, or Access Point Name (APN), or 5G QoS Indicator (5QI), or QCI (QoS Class Identifier) allocated to an additional session or additional bearer according to the operation of using the edge service application. can be defined as

Specifically, to describe an embodiment, it may be assumed that the base station apparatus 100 of the present invention is a standalone (SA) 5G base station.

In this case, according to the present invention, when the terminal 2 is a terminal subscribed to the edge service, the fact of the edge service subscription can be recognized from the terminal subscriber information of the terminal 2, so that the basic between the terminal 2 and the 5G core network When creating (or modifying) a connected communication path, that is, a basic session, an environment in which an edge service factor, for example, Slice ID for MEC, is allocated to a basic session according to terminal subscriber information of the terminal 2 may be assumed.

Alternatively, according to the present invention, according to the operation of using the edge service application executed for edge service use in the terminal 2, when necessary, the session ( An environment that additionally creates an additionally connected communication path) may be assumed.

Alternatively, according to the present invention, according to the use operation of the edge service application executed for edge service use in the terminal 2, if necessary, the bearer (additional additionally) It is possible to assume an environment that additionally creates a communication path connected to

Of course, a mapping rule related to an edge service factor (eg, Slice ID for MEC, 5QI for MEC) allocated to a basic session or an additional session or an additional bearer between the terminal 2 and the 5G core network, the corresponding terminal, the base station, and the core Sharing between networks will also be a prerequisite.

On the other hand, to describe another embodiment, it can be assumed that the base station apparatus 100 of the present invention is a TLE base station or a Non-Standalone (NSA) 5G base station.

In this case, according to the present invention, when the terminal 2 is a terminal subscribed to the edge service, the fact of the edge service subscription can be recognized from the terminal subscriber information of the terminal 2, so that the terminal 2 and the LTE or 5G core network An environment in which an edge service factor such as UUT or SPID is allocated to the basic session according to the terminal subscriber information of the terminal 2 may be assumed when a basic session is created (or modified), that is, a basic connection between the two communication paths.

Alternatively, according to the present invention, according to a usage operation of an edge service application executed for edge service use in the terminal 2, when necessary, a session (additional additionally It is possible to assume an environment that additionally creates a communication path connected to

Alternatively, according to the present invention, according to the use operation of the edge service application executed for edge service use in the terminal 2, when necessary, the bearer (additional additionally) It is possible to assume an environment that additionally creates a communication path connected to

Of course, a mapping rule related to an edge service factor (eg, UUT or SPID, APN for MEC, QCI for MEC) assigned to a basic session or an additional session or an additional bearer between the terminal 2 and the 5G core network, the corresponding terminal, Sharing between the base station and the core network will also be a prerequisite.

Assuming the environment set above, the terminal 2 internally converts data (packets) generated from the application when executing and using the edge service application as factors for edge service (eg, Slice ID for MEC, 5QI for MEC). , UUT or SPID, APN for MEC, QCI for MEC) will be transmitted to the assigned session or bearer.

Accordingly, the path control unit 120, the factor for edge service among the uplink data received through the data receiving unit 110 (eg, Slice ID for MEC, 5QI for MEC, UUT or SPID, APN for MEC, QCI for MEC) Uplink data received through the assigned session or bearer can be recognized/line separated into specific uplink data for which edge service provision determination is required, that is, traffic to be delivered to the edge node 20 .

As such, in the present invention, traffic to the edge node 20 (specific uplink data) by utilizing the communication path (session, bearer) establishment function between the terminal and the core network while maintaining and following the signaling between entities according to the 3GPP standard procedure without change ) line separation function can be realized.

Next, in the following, the realization of the function of setting the forwarding path differently so that only pre-separated traffic (specific uplink data) is transmitted to the edge node 20 will be described in detail.

In the present invention, a path-related node involved in a transmission path for transmitting uplink data to the core network, a first path-related node that induces a transmission path without an edge node, and a second path that induces a transmission path through the edge node It can be premised on a different operating environment as a related node.

In this case, the path-related node may be at least one of a virtual LAN (VLAN) and a default gateway.

That is, in the present invention, a VLAN and/or a default gateway used when transmitting uplink data (packets) from the base station to the core network is used to induce a forwarding path without passing through the edge node (first), forwarding through the edge node It is dualized for inducing a path (second), and a use/configuration relationship can be defined differently for each factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) previously used for traffic line separation.

Accordingly, to describe one embodiment in detail, the path control unit 120 defines a path-related node used when transmitting specific uplink data to the core network as an edge service factor of a communication path through which specific uplink data is received. It can be set as a specific second path-related node.

That is, the path control unit 120 (path-related node setting function 122) selects the path-related node used when transmitting the specific uplink data pre-separated as traffic to the edge node 20 in the above-mentioned manner to the core network. Factor for edge service of the communication path through which link data is received, that is, (basic or additional) session or bearer (eg Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, QCI for MEC) It can be set to a specific second path-related node (eg VLAN, default gateway) defined in .

In this case, the specific uplink data transmitted from the base station device 100 to the core network is an edge service factor (eg, Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, MEC for QCI) is encapsulated into a GTP protocol packet according to a delivery path by a specific second path-related node, for example, a specific second VLAN, and will be delivered to the edge node 20 .

Therefore, since only the traffic (specific uplink data) pre-separated by the base station device 100 is delivered to the edge node 20, the edge node 20 is analyzed based on only the pre-separated traffic (specific uplink data). It is possible to determine whether edge service is provided/branch to local.

On the other hand, the path control unit 120, the path-related node setting function 122) is a path-related node used when transmitting the remaining uplink data corresponding to the remaining traffic that does not need to be transmitted to the edge node 20 to the core network, Corresponding factors (e.g. Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, QCI for MEC) that the remaining uplink data is received through, that is, the (basic or additional) session or bearer. It can be set to a specific first route-related node (eg, VLAN, default gateway) defined in slice ID, 5QI, UUT, SPID, APN, QCI).

In this case, the remaining uplink data transmitted from the base station device 100 to the core network is a specific first defined factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) that is not an edge service factor. It is encapsulated into a GTP protocol packet according to a path-related node, for example, a forwarding path by a specific first VLAN, and will be delivered to a node (30, SGW or UPF, etc.) in the core network without passing through the edge node 20 .

Alternatively, in the present invention, an IP pool for an uplink endpoint (UL Endpoint) node in the core network allocated to uplink data is a first IP pool defined for a forwarding path without an edge node and an edge node It may be premised on an environment defined differently as the second IP pool defined for the passing path.

That is, in the present invention, the IP pool used in the process of generating (encapsulation) into GTP protocol packets for uplink data (packet) delivery from the base station to the core network is used for a delivery path without an edge node (the first) 1), for the delivery path via the edge node (2), and define the usage relationship differently for each factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) previously used for traffic line separation can do.

Accordingly, to describe one embodiment in detail, the path control unit 120, when transmitting the specific uplink data to the core network, a specific second IP defined in the edge service factor of the communication path through which the specific uplink data is received. You can allocate an IP for an uplink endpoint (UL Endpoint) node for specific uplink data within the pool.

That is, when the path control unit 120 (IP pool selection function 124) transmits the specific uplink data pre-separated as traffic to the edge node 20 in the above-mentioned manner to the core network, the communication in which the specific uplink data is received In other words, a specific second defined in the (basic or additional) session or edge service factor (eg, Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, QCI for MEC) that the (basic or additional) session or bearer has. By selecting/using an IP pool, an IP for an uplink endpoint (UL Endpoint) node for specific uplink data within a specific second IP pool may be allocated and generated (encapsulated) as a GTP protocol packet.

In this case, the specific uplink data transmitted from the base station device 100 to the core network is an edge service factor (eg, Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, MEC for QCI) will be encapsulated into a GTP protocol packet according to the forwarding path (allocated IP) by the specific second IP pool defined in the IP pool, and will be delivered to the edge node 20 .

Therefore, since only the traffic (specific uplink data) pre-separated by the base station device 100 is delivered to the edge node 20, the edge node 20 is analyzed based on only the pre-separated traffic (specific uplink data). It is possible to determine whether edge service is provided/branch to local.

On the other hand, the path control unit 120, the IP pool selection function 124) selects the path-related node used when transmitting the remaining uplink data corresponding to the remaining traffic that does not need to be transmitted to the edge node 20 to the core network. Corresponding factors (e.g. Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, QCI for MEC, Uplink endpoint (UL Endpoint) node for the remaining uplink data within a specific first IP pool by selecting / using a specific first IP pool defined in slice ID, 5QI, UUT, SPID, APN, QCI) You can allocate an IP for it and create (encapsulate) it as a GTP protocol packet.

In this case, the remaining uplink data transmitted from the base station device 100 to the core network is a specific first defined factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) that is not an edge service factor. It will be encapsulated into a GTP protocol packet according to the forwarding path (assigned IP) by the IP pool, and will be delivered to the node 30, SGW or UPF, etc. in the core network without going through the edge node 20.

As described above, in the present invention, a method and/or IP pool for setting path-related nodes (eg, VLAN, default gateway) differently for each pre-separated traffic (specific uplink data) and remaining traffic (remaining uplink data) By using a different method, it is possible to realize a function of differently setting a delivery path so that only pre-separated traffic (specific uplink data) is delivered to the edge node 20 .

In particular, in the present invention, while maintaining and following signaling between entities according to the 3GPP standard procedure without change, line-separated traffic (specific uplink data) and It is possible to realize the function of setting the forwarding path differently for each remaining traffic (remaining uplink data).

As described above, according to the embodiments of the present invention, in the ultra-edge environment, traffic to the edge node (MEC) is separated from the front end (eg, base station) of the edge node (MEC), and whether an analysis-based edge service is provided Realize a new technology (plan) that allows only the traffic that requires judgment to be selectively delivered to the edge node (MEC).

Furthermore, according to the embodiments of the present invention, since the signaling between entities according to the 3GPP standard procedure is maintained and followed without change in realizing the above new technology (plan), it is possible to immediately apply and commercialize it in the existing/current communication environment. There are advantages.

Meanwhile, the method realized/proposed in the present invention divides uplink data (Signaling) of the control-plane and uplink data (data traffic) of the user-plane that are incoming/received to/from the base station 100, and the user-plane It can be applied by targeting only uplink data (data traffic) of

In this case, the base station 100 according to the present invention requires specific traffic (specific uplink data) for which analysis-based edge service determination is required only for incoming/received user-plane uplink data (data traffic). can be pre-separated and the forwarding paths of specific traffic and the rest of the traffic are set differently, so that only specific traffic is delivered to the edge node (MEC).

In addition, the base station 100 according to the present invention sets the same transmission path without line separation as in the prior art for incoming/received uplink data (Signaling) of the control-plane, and is transmitted to the edge node (MEC). Signaling related to specific traffic and signaling related to the rest of the traffic delivered to the node (30, SGW or UPF, etc.) in the core network without passing through the edge node (MEC), all related nodes in the core network via the edge node (MEC) can be transmitted to

As described above, according to the present invention, since only traffic for which analysis-based edge service determination is required is selectively delivered to the edge node (MEC), various problems such as all traffic from the base station being delivered to the edge node (MEC) It is possible to improve problems such as capacity increase for traffic analysis/local branching at the edge node (MEC), user packet delay due to large-capacity traffic analysis, and performance (throughput) constraints, and the effect of improving the efficiency and service stability of edge services to derive

Hereinafter, a method of operating a base station apparatus according to an embodiment of the present invention will be described with reference to FIG. 4 .

For convenience of description, the following description will be described with reference to the reference numerals of FIG. 3 .

In the present invention, a path-related node involved in a transmission path for transmitting uplink data to the core network, a first path-related node that induces a transmission path without an edge node, and a second path that induces a transmission path through the edge node It may be premised on an environment operated differently as a related node (S10).

In this case, the path-related node may be at least one of a virtual LAN (VLAN) and a default gateway.

That is, in the present invention, a VLAN and/or a default gateway used when transmitting uplink data (packets) from the base station to the core network is used to induce a forwarding path without passing through the edge node (first), forwarding through the edge node It is dualized for inducing a path (second), and a use/configuration relationship can be defined differently for each factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) previously used for traffic line separation.

Hereinafter, for convenience of description, an example will be described by referring to VLAN as a path-related node.

In addition, in the present invention, an IP pool for an uplink endpoint (UL Endpoint) node in the core network allocated to uplink data is a first IP pool and an edge node defined for a forwarding path without an edge node. An environment that is defined differently as the second IP pool defined for the pass-through delivery path may be assumed (S20).

That is, in the present invention, the IP pool used in the process of generating (encapsulation) into GTP protocol packets for uplink data (packet) delivery from the base station to the core network is used for a delivery path without an edge node (the first) 1), for the delivery path via the edge node (2), and define the usage relationship differently for each factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) previously used for traffic line separation can do.

And, in the present invention, it is premised on an environment in which an edge service factor is allocated to a communication path that is basic or additionally connected according to at least one of terminal subscriber information and an operation of using the edge service application for each terminal (S30).

Here, the factor for edge service is Slice ID, or UE Usage Type (UUT), or Service Profile Identifier (SPID), which is assigned to a basic session according to terminal subscriber information, or the factor for edge service is the use of edge service applications. It may be defined as a Slice ID assigned to an additional session or an additional bearer according to an operation, or an Access Point Name (APN), or a 5G QoS Indicator (5QI), or a QoS Class Identifier (QCI).

Specifically, when the terminal 2 is a terminal subscribed to the edge service, the fact of the edge service subscription (MEC subscription or not) can be recognized from the terminal subscriber information of the terminal 2, so that between the terminal 2 and the core network When a basic connection is created (or modified), that is, when a basic session is created (or modified), an edge service factor (eg, Slice ID for MEC, UUT for MEC, SPID for MEC) is assigned to the basic session according to the terminal subscriber information of the terminal 2 It is possible to presuppose an environment in which the

Alternatively, according to the present invention, according to the operation of the edge service application (MEC app) executed for edge service use in the terminal 2, when necessary, the edge service factor (eg, Slice for MEC) in the terminal 2 ID, 5QI for MEC, APN for MEC, QCI for MEC) may assume an environment in which an additional session or an additional bearer is created (S30).

Assuming the environment set in the above, the terminal 2 internally executes and uses the edge service application (MEC app), using the data (packet) generated from the application as an edge service factor (eg, Slice ID for MEC). , 5QI for MEC, UUT or SPID, APN for MEC, QCI for MEC) will be transmitted to the assigned session or bearer.

Meanwhile, in the method of operating the base station apparatus according to the embodiment of the present invention, the base station apparatus 100 receives uplink data from the terminal (S40).

Accordingly, in the method of operating the base station apparatus according to the embodiment of the present invention, the base station apparatus 100 may include the received uplink data as an edge service factor (eg, Slice ID for MEC, 5QI for MEC, UUT or SPID, for MEC). It is checked whether APN, QCI for MEC) is received through the assigned session or bearer (S50).

That is, in the method of operating the base station apparatus according to the embodiment of the present invention, the base station apparatus 100 provides an edge service factor (eg, Slice ID for MEC, 5QI for MEC, UUT or SPID, MEC) among the received uplink data. Uplink data received through a session or bearer to which APN for MEC, QCI for MEC) is assigned (S50 Yes), specific uplink data for which it is required to determine whether edge service is provided, that is, traffic that needs to be delivered to the edge node 20 Cognitive/Line separation is possible.

In the operating method of the base station apparatus according to the embodiment of the present invention, the base station apparatus 100, specific uplink data among the received uplink data, that is, traffic to be transmitted to the edge node 20 (S50 Yes), the core As a path-related node used for transmission to the network, the edge service factor assigned to the session or bearer where specific uplink data was received this time (eg Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, MEC) A specific second path-related node defined in APN, QCI for MEC), for example, a specific second VLAN may be configured (S60).

Furthermore, in the operating method of the base station apparatus according to the embodiment of the present invention, the base station apparatus 100, among the received uplink data, specific uplink data, that is, traffic to be transmitted to the edge node 20 (S50 Yes) ), defined in the edge service factor (eg Slice ID for MEC, 5QI for MEC, UUT for MEC, SPID for MEC, APN for MEC, QCI for MEC) assigned to the session or bearer from which this specific uplink data was received. It is possible to select a specific second IP pool (S60).

In this case, when the base station apparatus 100 transmits the specific uplink data to the core network this time, using the specific second IP pool and/or the specific second VLAN previously set, the specific uplink data this time is specific. It will be encapsulated into a GTP protocol packet according to the delivery path by the second IP pool and/or the previously set specific second VLAN, and delivered to the edge node 20 (S70).

On the other hand, in the operating method of the base station apparatus according to the embodiment of the present invention, the base station apparatus 100 is specific uplink data among the received uplink data, that is, the remaining traffic (remaining uplink) that does not need to be transmitted to the edge node 20 . data) (S50 No), as a path-related node used for delivery to the core network, corresponding factors (eg, Slice ID, 5QI, UUT, SPID, APN, A specific first path-related node defined in QCI), for example, a specific first VLAN may be set (S65).

Further, in the operating method of the base station apparatus according to the embodiment of the present invention, the base station apparatus 100, for the remaining traffic (remaining uplink data) among the received uplink data (S50 No), this time the remaining uplink data may select a specific first IP pool defined in a corresponding factor (eg, Slice ID, 5QI, UUT, SPID, APN, QCI) allocated to the received session or bearer (S65).

In this case, when the base station apparatus 100 transfers the remaining uplink data to the core network this time, using the specific first IP pool selected above and/or the specific first VLAN set above, the specific uplink data this time is specific It is encapsulated into a GTP protocol packet according to the first IP pool and/or the forwarding path by the specific first VLAN set above, and to a node (30, SGW or UPF, etc.) in the core network without passing through the edge node 20. will be transmitted (S70).

Accordingly, according to the embodiments of the present invention, traffic to the edge node (MEC) is pre-separated in the ultra-edge environment so that only the traffic required to determine whether to provide an analysis-based edge service is selectively delivered to the edge node (MEC). Realize new technologies (plans) to

For this reason, according to the present invention, various problems caused by the transmission of all traffic from the base station to the edge node (MEC) can be improved, and the effect of improving the efficiency and service stability of the edge service is derived.

The method of operating a base station apparatus according to an embodiment of the present invention may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of the computer readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes 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.

Although the present invention has been described in detail with reference to preferred embodiments so far, the present invention is not limited to the above-described embodiments, and without departing from the gist of the present invention as claimed in the following claims, the technical field to which the present invention pertains It will be said that the technical idea of the present invention extends to the extent that any person with ordinary skill in the art can make various changes or modifications.

According to the operating method of the base station device and the base station device according to the present invention, in that the traffic to the edge node (MEC) is pre-separated and selectively delivered (via) in the ultra-edge environment, it goes beyond the limitations of the existing technology. It is an invention that has industrial applicability because the possibility of marketing or business of the applied device, not just the use of the technology, is sufficient and it can be clearly implemented in reality.

100: base station device
110: data receiving unit 120: path control unit

Claims (11)

In the base station device,
a data receiving unit for receiving uplink data from the terminal; and
With respect to an edge node that determines whether to provide an edge service by branching locally instead of a core network for all uplink data received from the base station apparatus, a specific uplink data in which edge service determination is required among the uplink data A path control unit characterized in that the uplink data received by the edge node from the base station apparatus is limited to the specific uplink data by different transmission paths to the core network for the link data and the remaining uplink data. Base station device, characterized in that. The method of claim 1,
For each terminal, an edge service factor is allocated to a communication path that is basic or additionally connected according to at least one of terminal subscriber information and an operation of using the edge service application;
The specific uplink data is,
The base station apparatus, characterized in that the uplink data received through the communication path to which the edge service factor is assigned. 3. The method of claim 2,
The factor for the edge service is,
Slice ID, or UE Usage Type (UUT), or Service Profile Identifier (SPID) assigned to a basic session according to terminal subscriber information, or
A base station, characterized in that it is defined as a Slice ID, or an Access Point Name (APN), or 5G QoS Indicator (5QI), or a QoS Class Identifier (QCI) allocated to an additional session or an additional bearer according to the operation of the edge service application. Device. 3. The method of claim 2,
The path-related node involved in the forwarding path for transmitting uplink data to the core network is different from the first path-related node for inducing a forwarding path without the edge node and the second path-related node for inducing the forwarding path through the edge node. operate;
The path control unit,
A base station apparatus characterized in that a path-related node used when transmitting the specific uplink data to the core network is set as a specific second path-related node defined in an edge service factor of a communication path through which the specific uplink data is received. . 5. The method of claim 4,
The path-related node is
A base station apparatus comprising at least one of a virtual LAN (VLAN) and a default gateway. 3. The method of claim 2,
An IP pool for an uplink endpoint node in the core network that is allocated to uplink data is defined for a forwarding path without an edge node. defined differently as a defined second IP pool;
The path control unit,
When delivering the specific uplink data to the core network, the uplink endpoint (UL) for the specific uplink data within a specific second IP pool defined in the factor for edge service of the communication path through which the specific uplink data is received Endpoint) base station device, characterized in that allocating an IP to the node. In the operating method of the base station apparatus,
A data receiving step of receiving uplink data from the terminal; and
With respect to an edge node that determines whether to provide an edge service by branching locally instead of a core network for all uplink data received from the base station apparatus, a specific uplink data in which edge service determination is required among the uplink data A path control step characterized in that the uplink data received by the edge node from the base station apparatus is limited to the specific uplink data by different transmission paths to the core network for the link data and the remaining uplink data. A method of operating a base station apparatus, characterized in that. 8. The method of claim 7,
For each terminal, an edge service factor is allocated to a communication path that is basic or additionally connected according to at least one of terminal subscriber information and an operation of using the edge service application;
The specific uplink data is,
The method of operating a base station apparatus, characterized in that the uplink data received through the communication path to which the edge service factor is assigned. 9. The method of claim 8,
The path-related node involved in the forwarding path for transmitting uplink data to the core network is different from the first path-related node for inducing a forwarding path without the edge node and the second path-related node for inducing the forwarding path through the edge node. operate;
The path control step is
A base station apparatus characterized in that a path-related node used when transmitting the specific uplink data to the core network is set as a specific second path-related node defined in an edge service factor of a communication path through which the specific uplink data is received. how it works. 10. The method of claim 9,
The path-related node is
A method of operating a base station apparatus, comprising at least one of a virtual LAN (VLAN) and a default gateway. 9. The method of claim 8,
An IP pool for an uplink endpoint node in the core network that is allocated to uplink data is defined for a forwarding path without an edge node. defined differently as a defined second IP pool;
The path control step is
When delivering the specific uplink data to the core network, the uplink endpoint (UL) for the specific uplink data within a specific second IP pool defined in the factor for edge service of the communication path through which the specific uplink data is received Endpoint) A method of operating a base station device, characterized in that allocating an IP to the node.

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