KR102245632B1 - Method and apparatus for managing bandwidth in a wireless communication system - Google Patents

Abstract

The present invention relates to a bandwidth management method and a mobile communication system configured with devices therefor. In a wireless access system according to an embodiment of the present invention, the bandwidth control method includes an MME ( Receiving, by a Mobility Management Entity), bandwidth information (Internet APN) corresponding to an Internet session of the terminal from a Home Subscriber Sever (HSS); When there is a request to create an Internet session for the terminal, and when both the first bandwidth information corresponding to 4G and the second bandwidth information corresponding to 5G exist in the bandwidth information obtained from the HSS, the MME serves as a Serving Gateway/ Transmitting a Create Session Request including the second bandwidth information to a PDN Gateway); Transmitting, by the MME, a Modify Bearer Request including the first bandwidth information to the SPGW; Creating an Internet session between the SPGW and the 4G base station for the terminal; And when the SPGW receives the bearer change request including the first bandwidth information, controlling the traffic to the terminal to a bandwidth corresponding to the 4G technology, and transmitting it to the 4G base station.

Description

A method and apparatus for controlling bandwidth in a wireless communication system.

The present invention relates to bandwidth control in a mobile communication network, and in more detail, in a situation where a communication network according to an advanced technology and an existing technology coexists, traffic of a bandwidth suitable for a base station corresponding to the movement of a terminal can be transmitted. It relates to a bandwidth control method and a mobile communication system configured with devices therefor.

The content described in this section merely provides background information on the present embodiment and does not constitute the prior art.

In the process of discussing the 5G structure at the general meeting of the 3GPP standards group, the demand to satisfy telecommunications operators in countries with rapid commercialization demand before 2020 and that it takes time to research and create standard technologies that can create new services. A request was made.

In the process of discussing these two conflicting demands, various post-structural security were discussed, and as a result of the discussion, as a result of the discussion, a new 5G standard NR (New Radio) technology was used as an existing 4G standard, 3GPP LTE (Long). The 　Non Standalone (NSA) 　 structure was introduced to provide LTE coverage and NR coverage at the same time by using together with the Term Evolution) system.

Under the current NSA structure, 5G service is a method of changing a path (ie, a session) through which the terminal sends and receives data in order to improve the data processing speed between the terminal and the network based on the existing 4G service. For example, if a terminal supporting 5G (hereinafter, referred to as “5G terminal” for convenience) is within NR coverage, it communicates with a 5G base station (gNB), and if it is within LTE coverage, it communicates with a 4G base station (eNB). Of course, a path for a voice call, that is, an IP Multi-Media Subsystem (IMS) session, maintains a 4G base station regardless of its location to improve call quality.

However, when the 5G terminal is located within the LTE coverage, the mobile communication network operator needs to manage the network so that the customer service using the existing 4G service is not affected. However, in the current 5G standard, a bandwidth corresponding to 5G technology is allocated regardless of the location of the 5G terminal. For example, even if a 5G terminal is in LTE coverage and communicates with a 4G base station, the 5G bandwidth is allocated to the terminal. Therefore, when traffic destined for the corresponding terminal is transmitted, since the 5G bandwidth traffic is transmitted to the 4G base station, there is a problem in that a service failure of a customer using a 4G service may occur due to an overload.

The present invention was devised to solve the problems of the prior art described above, and an object of the present invention is a bandwidth management method capable of transmitting traffic to a corresponding base station with a bandwidth corresponding to the location of a 5G terminal, and a mobile communication comprising devices therefor It is to provide a system.

As an embodiment, the present invention provides a bandwidth management method for defining a procedure for creating or changing an Internet session so that traffic can be transmitted to a corresponding base station with a bandwidth corresponding to the location of a 5G terminal, and a mobile communication system composed of devices therefor. To provide.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned will be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. I will be able to.

The present invention can provide a bandwidth management method and a mobile communication system composed of devices therefor.

In a method for controlling bandwidth in a wireless access system according to an embodiment of the present invention, a Mobility Management Entity (MME) corresponds to an Internet session of the terminal from a Home Subscriber Server (HSS) according to an Attach Request of a specific terminal. Receiving bandwidth information (Internet APN); When there is a request to create an Internet session for the terminal, and when both the first bandwidth information corresponding to 4G and the second bandwidth information corresponding to 5G exist in the bandwidth information obtained from the HSS, the MME serves as a Serving Gateway/ Transmitting a Create Session Request including the second bandwidth information to a PDN Gateway); Transmitting, by the MME, a Modify Bearer Request including the first bandwidth information to the SPGW; Creating an Internet session between the SPGW and the 4G base station for the terminal; And when the SPGW receives the bearer change request including the first bandwidth information, controlling the traffic to the terminal to a bandwidth corresponding to the 4G technology, and transmitting it to the 4G base station.

For example, the first bandwidth information may be set as an aggregated maximum bit rate (AMBR) type, and the second bandwidth information may be set as an extended AMBR type.

For example, the Modify Bearer Request may include an Internet APN information area set to the AMBR type.

For example, the bandwidth control method includes the steps of receiving, by the MME, an E-RAB Modification Indication from the 4G base station; It may further include transmitting a bearer change request including bandwidth information corresponding to the current location of the terminal indicated by the E-RAB Modification Indication to the SPGW.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is NR (New Radio) coverage corresponding to a 5G base station, a bearer change request including bandwidth information corresponding to the current location of the terminal is It may include an Internet APN information area set to the Extended AMBR type.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is the NR coverage, the terminal attempts an initial access in the NR coverage, or the terminal is an LTE corresponding to the 4G base station ( Long Term Evolution) may include a case of moving from coverage to the NR coverage.

For example, the bandwidth control method may further include changing an Internet session between the SPGW and the 4G base station to an Internet session between the SPGW and the 5G base station.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is LTE (Long Term Evolution) coverage corresponding to the 4G base station, change the bearer including bandwidth information corresponding to the current location of the terminal The request may include an Internet APN information area set to the AMBR type.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is the LTE coverage, it includes the case that the terminal moves from the NR (New Radio) coverage corresponding to the 5G base station to the LTE coverage. can do.

For example, regardless of the location of the terminal, an IP Multi-Media Subsystem (IMS) session may be maintained between the SPGW and the 4G base station.

In addition, a wireless access system according to an embodiment of the present invention includes: a Home Subscriber Server (HSS); Serving Gateway/PDN Gateway (SPGW); A 4G base station for receiving an Attach Request from a specific terminal; And when the connection request is received through the 4G base station, bandwidth information (Internet APN) corresponding to the Internet session of the terminal is received from the HSS, and first bandwidth information corresponding to 4G in the bandwidth information obtained from the HSS. When both the second bandwidth information corresponding to the 5G and the 5G exist, an MME that transmits a Create Session Request including the second bandwidth information to the SPGW in response to an Internet session creation request for the terminal ( Mobility Management Entity). Here, the SPGW is, after the session creation request is received, when a bearer change request including the first bandwidth information is received from the MME, the Internet session between the SPGW and the 4G base station for the terminal is As generated, the traffic to the terminal can be controlled by a bandwidth corresponding to the 4G technology and transmitted to the 4G base station.

For example, the first bandwidth information may be set as an aggregated maximum bit rate (AMBR) type, and the second bandwidth information may be set as an extended AMBR type.

For example, the Modify Bearer Request may include an Internet APN information area set to the AMBR type.

For example, when the MME receives an E-RAB Modification Indication from the 4G base station, the MME transmits a bearer change request including bandwidth information corresponding to the current location of the UE indicated by the E-RAB Modification Indication to the SPGW. I can.

For example, the radio access system further includes a 5G base station, and if the current location of the terminal indicated by the E-RAB Modification Indication is NR (New Radio) coverage corresponding to the 5G base station, the current A bearer change request including bandwidth information corresponding to a location may include an Internet APN information area set to the Extended AMBR type.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is the NR coverage, the terminal attempts an initial access in the NR coverage, or the terminal is an LTE corresponding to the 4G base station ( Long Term Evolution) may include a case of moving from coverage to the NR coverage.

For example, as a bearer change request including bandwidth information corresponding to the current location of the terminal is transmitted to the SPGW, the Internet session between the SPGW and the 4G base station is changed to an Internet session between the SPGW and the 5G base station, Wireless access system.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is LTE (Long Term Evolution) coverage corresponding to the 4G base station, change the bearer including bandwidth information corresponding to the current location of the terminal The request may include an Internet APN information area set to the AMBR type.

For example, when the current location of the terminal indicated by the E-RAB Modification Indication is the LTE coverage, it includes the case that the terminal moves from the NR (New Radio) coverage corresponding to the 5G base station to the LTE coverage. can do.

For example, regardless of the location of the terminal, an IP Multi-Media Subsystem (IMS) session may be maintained between the SPGW and the 4G base station.

The aspects of the present invention are only some of the preferred embodiments of the present invention, and various embodiments reflecting the technical features of the present invention will be described in detail below by those of ordinary skill in the art. It can be derived and understood on the basis of.

The effect of the method and apparatus according to the present invention will be described as follows.

According to an embodiment of the present invention, since a procedure for creating or changing an Internet session with a bandwidth corresponding to a location of a 5G terminal is defined, there is an advantage in that an overload problem of a base station can be solved.

In particular, in the present invention, since the MME notifies the SPGW of bandwidth information corresponding to the location of the 5G terminal through the bearer change procedure, there is an advantage in that an Internet session can be created or changed with a bandwidth corresponding to the location of the 5G terminal.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings are provided to aid understanding of the present invention and provide embodiments of the present invention together with a detailed description. However, the technical features of the present invention are not limited to a specific drawing, and features disclosed in each drawing may be combined with each other to constitute a new embodiment.
1 is a block diagram of a mobile communication system according to an embodiment.
2 is a diagram illustrating a structure of an SA and NSA (EN-DC) system supporting the use of 5G NR according to an embodiment.
3 is a diagram illustrating a detailed structure of a 5G NSA system according to an embodiment.
4 is a diagram illustrating a situation in which an overload of a 4G base station occurs when a 5G terminal accesses a network within LTE coverage.
5 is a diagram illustrating an example of a network access procedure of a 5G terminal according to an embodiment of the present invention.
6 shows an example of an Internet session change procedure when a 5G terminal moves from LTE coverage to NR coverage according to an embodiment of the present invention.
7 shows an example of an Internet session change procedure when a 5G terminal moves from NR coverage to LTE coverage according to an embodiment of the present invention.

Hereinafter, an apparatus and various methods to which embodiments of the present invention are applied will be described in more detail with reference to the drawings. The suffixes "module" and "unit" for constituent elements used in the following description are given or used interchangeably in consideration of only the ease of preparation of the specification, and do not have meanings or roles that are distinguished from each other by themselves.

In the description of the embodiment, in the case of being described as being formed on the “top (top) or bottom (bottom)” of each component, the top (top) or bottom (bottom) is that the two components are in direct contact with each other, or It includes all of the one or more other components formed by being disposed between the two components. In addition, when expressed as "upper (upper) or lower (lower)", the meaning of not only an upward direction but also a downward direction based on one component may be included.

1 is a diagram illustrating a structure of a mobile communication network according to an embodiment.

The mobile communication network according to the present invention may be configured based on the 4G standard 3GPP LTE (Long Term Evolution) and/or the 5G standard NR (New Radio), but this is only one embodiment, and the 4G standard and the 5G It can be configured to interwork with devices of a network other than the network element defined in the standard-for example, an IoT network.

Referring to FIG. 1, a mobile communication network according to an embodiment includes User Equipment (UE) 10, evolved Node B (eNB, 20), Serving Gateway (S-GW) 30, and Packet Data Network Gateway (P-GW) 40. ), MME (Mobility Management Entity, 50), HSS (Home Subscriber Server, 60), SPR (Subscriber Profile Repository, 70), OFCS (Offline Charging System, 80), OCS (Online Charging System, 90), PCRF (Policy and Charging Rule Function, 100).

The UE 10 is a user terminal conforming to the LTE and/or NR standard, and may connect the LTE Uu interface 15 with the eNB 20. Here, the LTE Uu interface 15 is a wireless interface and defines a control plane for transmitting and receiving a control message and a user plane for providing user data.

The UE 10 according to an embodiment may also interwork with gNB, which is a base station supporting the NR standard, or en-gNB, which is a base station supporting both LTE and NR standards.

The eNB 20 is a device that provides a radio interface to the UE 10 and provides radio resource management functions such as radio bearer control, radio admission control, dynamic radio resource allocation, load balancing, and inter-cell interference control. do.

S-GW (30) is the end of the E-UTRAN (Evolved Universal Terrestrial Radio Access Network) and Evolved Packet Core (EPC), the anchoring point (Anchoring point) when handover between eNBs (20) and handover between 3GPP systems do. Here, the E-UTRAN is composed of at least one eNB (20), and the EPC is composed of S-GW (30), P-GW (40) and MME (50).

The P-GW 40 connects the UE 10 with an external PDN (Packet Data Network) 110 and performs a packet filtering function.

In addition, the P-GW 40 allocates an IP address to the UE 10 and operates as a mobility anchoring point during handover between the 3GPP system and the non-3GPP system.

In particular, the P-GW (40) receives the PCC (Policy and Charging Control) rule from the PCRF (100), applies it to the service flow, and provides a charging function for each UE (10) / Service Date Flow (SDF). do.

The MME 50 provides an access control function for network connection of the UE 10, a network resource allocation function, a tracking function, a paging function, a roaming function, a handover function, etc. can do.

The MME 50 may manage a plurality of eNBs 20 and select a gateway by performing predetermined signaling for handover to an existing 2G/3G network.

In addition, the MME 50 may perform an authentication and security setting procedure for the accessing UE 10 in conjunction with the HSS 60, and may manage location information for idle terminals.

The MME 50 may obtain an authentication vector from the HSS 60 and perform mutual authentication with the UE 10 using the authentication vector. When the authentication procedure is completed, the MME 50 may set a security key for security between the UE 10 and the MME 50.

Another function of the MME 50 will become clearer through the description of the drawings to be described later.

The HSS 60 is a database in which a subscriber profile is stored, and provides user authentication information and a user profile to the MME 50.

The SPR 70 provides subscriber and subscription-related information to the PCRF 100, and the PCRF 100 generates a subscriber-based PCC rule using the subscriber and subscription-related information.

OFCS (80) provides charging information based on CDR (Charging Data Record).

The OCS 90 provides a billing function based on volume, time, and event through real-time credit control.

The PCRF 100 is an entity that performs policy and billing control and provides a policy control decision and billing control function. The PCC rule generated by the PCRF 100 is transmitted to the P-GW 40.

The PCRF 100 and the P-GW 40 according to the embodiment may interwork with an IP Multimedia Subsystem (IMS) network that provides various IP services of mobile operators.

Hereinafter, an interface between elements constituting an LTE network will be briefly described.

The LTE-Uu 15 provides a control plane and a user plane as a radio interface between the UE 10 and the eNB 20.

The S1-U 25 is an interface between the eNB 20 and the S-GW 30 and provides a user plane. At this time, GTP tunneling for each bearer is provided.

The S5 (35) is an interface between the S-GW (30) and the P-GW (40), and provides a control plane and a user plane. At this time, the user plane provides GTP tunneling for each bearer, and the control plane provides GTP tunnel management.

The SGi 45 defines a user plane and a control plane as an interface between the P-GW 40 and the PDN 110. IETF-based IP packet forwarding protocol is used in the user plane, and protocols such as DHCP and RADIUS/Diameter are used in the control plane.

S11 (55) is an interface between the MME (50) and the S-GW (30), the control plane is defined, and GTP tunneling is provided per bearer.

The X2 65 is an interface between two eNBs 20 or two base stations that support Radio Access Technology (RAT) between each other, and provides a control plane and a user plane. In the control plane, the X2-AP protocol is used, and in the user plane, GTP (GPRS Tunneling Protocol) tunneling is provided per bearer for data forwarding during X2 handover.

S6a (75) is an interface between the HSS (60) and the MME (50) is provided with a control plane, and is used to exchange UE subscription information and authentication information.

Gx (85) is an interface between the PCRF (100) and the P-GW (40), a control plane is defined, and is used to deliver a policy control rule and billing rule for QoS (Quality of Service) policy and billing control. .

Sp (95) is an interface between the SPR (70) and PCRF (100), a control plane is defined, and is used to deliver a user profile.

Gz 105 is an interface between the OFCS 80 and the P-GW 40, a control plane is defined, and is used for CDR transmission from the P-GW 40 to the OFCS 80.

Gy (115) is an interface between the OCS (90) and the P-GW (40), a control plane is defined, and is used for real-time credit (Credit) control information exchange.

The S1-AP 125 is an interface between the eNB 20 and the MME 50, and a control plane is defined, and is used for exchanging control information for mobility management.

FIG. 2 is a diagram illustrating a structure of an SA and NSA (EN-DC) system supporting the use of 5G NR according to an embodiment.

Figure 2 (a) shows a stand alone (SA) structure that provides only NR coverage, and Figure 2 (b) uses NR (New Radio) technology together with an existing LTE system to provide LTE coverage and NR coverage at the same time. It represents the structure of Non Standalone (NSA), respectively.

The following three types of base station types may be defined in the SA system and the NSA system supporting the use of 5G NR of FIG. 2.

1) eNB: A base station used in an LTE system that supports interworking between LTE technology and EPC (Enhanced Packet Core).

2) gNB: Next-generation base station that supports interworking with NR technology and 5G Core

3) en-gNB: A new type of base station that supports interworking with NR technology and 5G Core, and at the same time interlocks with the core of the LTE system 　EPC and the eNB, which is a base station.

Of the three base station types, gNB is used only in the 5G SA structure, as shown in FIG. 2A.

This is because in the 5G SA structure, the UE uses only the resources of the gNB controlled by the NR technology.

In contrast, the UE in the 5G NSA structure uses not only the resources of the eNB supporting LTE technology, but also the resources of the en-gNB supporting NR technology while interworking with the eNB and EPC.

As shown in (b) of FIG. 2, a technology in which a terminal supporting one or more RX/TX simultaneously uses a resource controlled by one or more base stations is called Dual Connectivity (DC).The 5G NSA structure is DC defined by the 3GPP standard organization. It is based on technology.

3 is a diagram illustrating a detailed structure of a 5G NSA system according to an embodiment.

The 5G NSA structure in the current 3GPP standard not only supports the use of NR in the Master Node (MN) or Secondary Node (SN), but also supports the use of the 5G Core or EPC for the core network.

The standard is defined to support various combinations of NSA structures, but in reality, in the case of a telecommunications operator using an LTE system composed of EPC and LTE macro base stations as a nationwide network, the structure of the combination that utilizes the existing LTE system to the maximum is fast 5G. It is being considered for commercialization.

As an example, the 5G NSA structure may be the structure of FIG. 4 in which the EPC of the LTE system is used as a core network, the eNB, which is an LTE base station, is used as the MN, and the en-gNB, which is an NR base station, is used as the SN.

An eNB operating as an MN can relay the transmission and reception of NAS (Nan Access Stratum) messages between the MME and the UE by creating an S1-MME control connection with the control entity MME of the EPC, which is the core of the LTE system.

The NAS layer is the uppermost layer of the control plane and can transmit and receive control messages between the MME and the UE. NAS messages include Mobility Management Messages such as location registration messages and handover messages, Session Management Messages related to session establishment and termination, and authentication and security related messages related to subscriber authentication and message security. Can include.

In addition, the eNB may create a radio resource control (RRC) connection with the UE using LTE radio technology, and manage the RRC state based on the RRC connection.

The en-gNB operating as an SN does not participate in the control connection related to the EPC and relaying of NAS messages, but can only participate in the additional data connection for transmitting and receiving high-capacity data.

The en-gNB, which transmits and receives data through an additional data connection, can transmit and receive data to and from the EPC using one of the following two paths, unlike the eNB, which is an MN.

The first path may be a PGW/SGW<-->eNB<-->en-gNB connection path for transmitting and receiving data through an eNB.

In this path, the eNB, the MN, acts as a split node that divides the first data that is directly sent to the UE using LTE radio resources and the second data that transmits data to the UE using NR resources through en-gNB. You can do it.

The second path is a PGW/SGW<-->en-gNB connection path that transmits and receives data directly to and from the PGW/SGW.

In this path, the SGW may serve as a split node that divides the first data transmitted and received with the UE through the eNB and the second data transmitted and received with the UE through the en-gNB.

Which one of the above two connection paths is used for data transmission/reception between the SN and the EPC may be determined according to a choice of a person skilled in the art.

As described above, in the current 5G standard, the bandwidth corresponding to the 5G technology is allocated regardless of the location of the 5G terminal, so when a 5G terminal is located within the LTE coverage, the traffic for the corresponding terminal is transmitted to the 4G base station in the 5G bandwidth. Therefore, an overload may occur. This situation will be described with reference to FIG. 4.

4 is a diagram illustrating a situation in which an overload of a 4G base station occurs when a 5G terminal accesses a network within LTE coverage. In the following drawings and related descriptions including FIG. 4, illustration of a 5G terminal is omitted for clarity of understanding.

Referring to FIG. 4, as a 5G terminal is located within LTE coverage, an Attach Request is transmitted to a mobility management entity (MME) among network devices in order to access a network through a 4G base station (eNB) (S401). .

Upon receiving the Attach Request, the MME may negotiate with the HSS to check the subscription information of the UE and obtain a UE context. For example, the MME may transmit an Update Location Request to the HSS (S402), and receive an Update Location Answer in response thereto (S403). Here, the Update Location Answer may include bandwidth information corresponding to a session for a voice call of a corresponding terminal and bandwidth information corresponding to a session for data transmission through a data connection.

The session for a voice call may be an IMS session, and bandwidth information corresponding thereto (i.e., IMS APN) is included in an Aggregated Maximum Bit Rate (AMBR) type when a 4G base station is maintained regardless of a location to improve call quality.

In addition, a session for data transmission through a data connection may be an Internet session, and bandwidth information (ie, Internet APN) corresponding thereto includes both AMBR and Extended AMBR types since the corresponding terminal is a 5G terminal.

The MME stores 4G bandwidth information (AMBR) and 5G bandwidth information (Extended AMBR) for the corresponding terminal, respectively, and proceeds with the IMS session creation procedure for the 5G terminal that transmitted the Attach Request as follows.

First, the MME transmits a Create Session Request to a Serving Gateway/PDN Gateway (SPGW) to provide a bearer connection for an IMS session, and the SPGW responds to the Create Session Request as a Create Session Response (S404). At this time, since the IMS session maintains the 4G base station, the IMS APN information of the Create Session Request is set to AMBR.

Upon receiving the Create Session Response, the MME transmits the Attach Accept message and bearer context information to the eNB, and when the bearer connection with the UE is established, the eNB transmits Attach Complete to the MME (S405).

Meanwhile, the MME proceeds with the SPGW and bearer change procedure. To this end, the MME transmits a Modify Bearer Request to the SPGW, and the SPGW responds to the MME with a Modify Bearer Response after establishing a bearer connection with the eNB (S406).

Through this procedure, the IMS session creation procedure between the eNB and the SPGW is completed (S407).

When an IMS session is created, the 5G terminal requests Internet session creation, and accordingly, the eNB transmits a PDN Connectivity Request to the MME (S408).

Accordingly, the MME transmits a Create Session Request to the SPGW to provide a bearer connection for an Internet session to the terminal (S409).If the terminal is a 5G terminal, the current standard provides Internet APN information regardless of the current location of the terminal. In step S403, the extended ABMR type obtained from the HSS is set.

Accordingly, the SPGW sets the bandwidth for the 5G terminal as an extended ABMR type and performs a response to the Create Session Request as a Create Session Response (S410).

Upon receiving the Create Session Response, the MME exchanges a PDN Connectivity Accept/Complete message with the eNB (S411).

Thereafter, as the MME and SPGW proceed with the bearer change procedure (S412), the Internet session creation procedure for the corresponding terminal is completed (S413).

However, as described above, in step S409, the bandwidth for the corresponding terminal is set to the extended ABMR type regardless of the current location of the terminal. That is, when the Internet APN information of the terminal obtained from the HSS includes both the Extended ABMR type and the ABMR type, the MME always sets the Internet APN to the Extended ABMR type in the Create Session Request message.

Therefore, even if the traffic for the corresponding terminal enters the SPGW in the 5G bandwidth (S414), the SPGW delivers the traffic as it is to the eNB in the 5G bandwidth without separate bandwidth control (S415), so that the eNB, which has a lower capacity than the gNB, is overloaded. Can occur.

In order to solve this problem, in an embodiment of the present invention, in creating or changing an Internet session for a 5G terminal, the MME transmits bandwidth information (Internet APN) corresponding to the current location of the 5G terminal to the SPGW through a bearer change procedure. Suggest to provide. In addition, through this, when the terminal is located within the current LTE coverage, it is proposed that the SPGW controls the traffic for the terminal with a bandwidth corresponding to 4G and transmits it to the eNB. The network access procedure according to this embodiment will be described with reference to FIG. 5.

5 is a diagram illustrating an example of a network access procedure of a 5G terminal according to an embodiment of the present invention.

In FIG. 5, it is assumed that a 5G terminal performs initial network access within LTE coverage. In addition, since the procedure (S501) for generating the IMS session from the initial access request of the 5G terminal in FIG. 5 is the same as steps S401 to S407 of FIG. 4, duplicate descriptions will be omitted for simplicity of the specification.

When the IMS session is created, the 5G terminal requests Internet session creation, and accordingly, the eNB transmits a PDN Connectivity Request to the MME (S508).

Accordingly, the MME transmits a Create Session Request to the SPGW to provide a bearer connection for the Internet session to the terminal (S509).Since the terminal is a 5G terminal, set the Internet APN information to the Extended ABMR type obtained from the HSS. do.

Accordingly, the SPGW sets the bandwidth for the 5G terminal as an extended ABMR type and performs a response to the Create Session Request as a Create Session Response (S510).

Upon receiving the Create Session Response, the MME exchanges a PDN Connectivity Accept/Complete message with the eNB (S411).

Thereafter, the MME and SPGW proceed with the bearer change procedure, but in this embodiment, the MME includes the Internet APN information area set to the AMBR type in the Modify Bearer Request message and transmits it to the SPGW (S512). In this case, the AMBR value may be an AMBR value for a corresponding terminal transmitted from the HSS, but is not limited thereto.

As the SPGW responds to the MME with a Modify Bearer Response message (S513), the Internet session creation procedure for the corresponding terminal is completed (S514).

In this case, since the SPGW resets the bandwidth for the 5G terminal to the AMBR type, that is, to the 4G level through the bearer change procedure, even if the traffic corresponding to the 5G bandwidth enters the terminal (S515), through the bandwidth control ( S516) The traffic corresponding to the 4G technology is delivered to the eNB (S517). In this case, the bandwidth of the 4G level may be a size corresponding to the AMBR type described above, and may vary according to the processing capacity of the eNB, but may be a range generally allocated to one 4G terminal.

Therefore, even if the 5G terminal accesses the 4G base station (eNB) within the LTE coverage, there is no fear of overloading because traffic with an excessive bandwidth is not introduced to the eNB due to the bandwidth control of the SPGW.

Hereinafter, a bandwidth control procedure according to a position movement of a 5G terminal after initial access will be described with reference to FIGS. 6 and 7.

6 shows an example of an Internet session change procedure when a 5G terminal moves from LTE coverage to NR coverage according to an embodiment of the present invention.

The procedure shown in FIG. 6 may be applied when a terminal accessing the network within LTE coverage moves to NR coverage as shown in FIG. 5, and the terminal accessing the network within NR coverage from the beginning is a 5G base station (gNB). It may be a procedure that proceeds after going through the procedure of FIG. 5 in order to receive a service from. In other words, when a 5G terminal accesses a network within NR coverage from the beginning, the processes of FIGS. 5 and 6 may constitute an initial network access procedure. For convenience of explanation, in the following description, it is assumed that a terminal accessing a network within LTE coverage moves to NR coverage.

Referring to FIG. 6, first, as the eNB recognizes the location change of the UE, E-RAB including information indicating that the UE moves from LTE coverage to NR coverage (i.e., 4G->5G) for data path change. Transmits a Modification Indication message to the MME (S610).

Accordingly, the MME includes the Internet APN information area set to the Extended AMBR type in the Modify Bearer Request message and transmits it to the SPGW (S620). In this case, the extended AMBR value may be an extended AMBR value for the corresponding terminal transmitted from the HSS.

When the SPGW responds to the MME with a Modify Bearer Response message (S630), the MME transmits an E-RAB Modification Confirm message indicating that the location change of the UE is confirmed to the eNB (S640).

Even if the location of the terminal is changed, since the voice call uses the eNB, the IMS session is maintained as it is (S650), but the Internet session may be changed to use the gNB as the data path (S660). Therefore, when the terminal is located in NR coverage, the bandwidth for the terminal set in the SPGW in the procedure of FIG. 5 is changed from the AMBR type to the extended AMBR type. It can be directly delivered to the gNB (S670). As a result, the 5G terminal can normally receive a high-speed data service corresponding to the 5G bandwidth within the NR coverage.

7 shows an example of an Internet session change procedure when a 5G terminal moves from NR coverage to LTE coverage according to an embodiment of the present invention. 7 may be a process subsequent to FIG. 6.

Referring to FIG. 7, first, as the eNB recognizes the location change of the UE, the UE moves from NR coverage to LTE coverage to change the data path (E-RAB: E-UTRAN Radio Access Bearer) (i.e., 5G- >4G) and transmits an E-RAB Modification Indication message including information indicating the MME (S710).

Accordingly, the MME includes the Internet APN information area set to the AMBR type in the Modify Bearer Request message and transmits it to the SPGW (S720). In this case, the AMBR value may be an AMBR value for the corresponding terminal received from the HSS.

When the SPGW responds to the MME with a Modify Bearer Response message (S730), the MME transmits an E-RAB Modification Confirm message indicating that the location change of the UE is confirmed to the eNB (S740).

Even if the terminal was in the previous NR coverage, since the voice call was still using the eNB, the IMS session is maintained as it is (S750), but the Internet session may be changed to use the eNB as the data path (S760).

In this case, since the SPGW resets the bandwidth for the 5G terminal to the AMBR type, that is, to the 4G level through the bearer change procedure, even if the traffic corresponding to the 5G bandwidth enters the terminal (S770), through the bandwidth control ( S780) Traffic corresponding to the 4G technology is delivered to the eNB (S790).

Therefore, even if the 5G terminal moves from the NR coverage to the LTE coverage, there is no fear of overloading because traffic with an excessive bandwidth is not introduced to the eNB due to the bandwidth control of the SPGW.

In the above, even if all the components constituting the embodiments of the present invention are described as being combined into one and operating, the present invention is not necessarily limited to these embodiments. That is, within the scope of the object of the present invention, all the constituent elements may be selectively combined and operated in one or more. In addition, although all of the components may be implemented as one independent hardware, a program module that performs some or all functions combined in one or more hardware by selectively combining some or all of the components. It may be implemented as a computer program having Codes and code segments constituting the computer program may be easily deduced by those skilled in the art. Such a computer program is stored in a computer-readable storage medium, and is read and executed by a computer, thereby implementing an embodiment of the present invention. The storage medium of the computer program may include a magnetic recording medium, an optical recording medium, and the like.

In addition, terms such as "include", "consist of" or "have" described above mean that the corresponding component may be embedded unless otherwise stated, excluding other components. It should not be construed as being able to further include other components. All terms, including technical or scientific terms, unless otherwise defined, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms generally used, such as terms defined in the dictionary, should be interpreted as being consistent with the meaning in the context of the related technology, and are not interpreted as ideal or excessively formal meanings unless explicitly defined in the present invention.

In addition, in describing the constituent elements of the present invention, terms such as first, second, A, B, (a) and (b) may be used. These terms are for distinguishing the constituent element from other constituent elements, and the nature, order, or order of the constituent element is not limited by the term. If a component is described as being "connected", "defective" or "connected" to another component, that component may be directly connected or connected to that other component, but another component between each component It will be understood that an element may be “connected”, “defective” or “connected”.

The above-described methods may be implemented as computer-readable codes on a computer-readable recording medium. Computer-readable recording media include all types of recording media in which data that can be decoded by a computer system are stored. For example, there may be read only memory (ROM), random access memory (RAM), magnetic tape, magnetic disk, flash memory, optical data storage device, and the like. In addition, the computer-readable recording medium may be distributed to a computer system connected through a computer communication network, stored as a code that can be read in a distributed manner, and downloaded to the corresponding device to be executed.

In addition, although the above has been described with reference to preferred embodiments of the present invention, those of ordinary skill in the relevant technical field can use the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. It will be appreciated that various modifications and changes can be made.

Claims (20)

Receiving, by a Mobility Management Entity (MME) from a Home Subscriber Server (HSS), bandwidth information (Internet APN) corresponding to an Internet session of the terminal according to an Attach Request of a specific terminal;
When there is a request to create an Internet session for the terminal, and when both the first bandwidth information corresponding to 4G and the second bandwidth information corresponding to 5G exist in the bandwidth information obtained from the HSS, the MME serves as a Serving Gateway/ Transmitting a Create Session Request including the second bandwidth information to a PDN Gateway);
Transmitting, by the MME, a Modify Bearer Request including the first bandwidth information to the SPGW;
Creating an Internet session for the terminal between the SPGW and the 4G base station; And
When the SPGW receives the bearer change request including the first bandwidth information from the MME, controlling the traffic for the terminal to a bandwidth corresponding to the 4G technology, and transmitting it to the 4G base station,
The first bandwidth information included in the bearer change request,
It is obtained from the HSS before the Internet session is created, a bandwidth control method in a wireless access system. The method of claim 1,
The first bandwidth information is set to AMBR (Aggregated Maximum Bit Rate) type,
The second bandwidth information is set to an extended AMBR type, a bandwidth control method in a wireless access system. The method of claim 2,
The bearer change request (Modify Bearer Request),
A method of controlling bandwidth in a wireless access system, including an Internet APN information area set to the AMBR type. The method of claim 2,
Receiving, by the MME, an E-RAB Modification Indication from the 4G base station;
Transmitting a bearer change request including bandwidth information corresponding to the current location of the terminal indicated by the E-RAB Modification Indication to the SPGW. The method of claim 4,
When the current location of the terminal indicated by the E-RAB Modification Indication is NR (New Radio) coverage corresponding to a 5G base station,
A method of controlling bandwidth in a wireless access system, wherein the bearer change request including bandwidth information corresponding to the current location of the terminal includes an Internet APN information area set to the Extended AMBR type. The method of claim 5,
When the current location of the terminal indicated by the E-RAB Modification Indication is the NR coverage,
A method for controlling bandwidth in a wireless access system, including a case where the terminal attempts an initial access in the NR coverage, or the terminal moves from a Long Term Evolution (LTE) coverage corresponding to the 4G base station to the NR coverage. The method of claim 5,
The step of changing an Internet session between the SPGW and the 4G base station to an Internet session between the SPGW and the 5G base station. The method of claim 4,
When the current location of the terminal indicated by the E-RAB Modification Indication is LTE (Long Term Evolution) coverage corresponding to the 4G base station,
A method of controlling bandwidth in a wireless access system, wherein the bearer change request including bandwidth information corresponding to the current location of the terminal includes an Internet APN information area set to the AMBR type. The method of claim 8,
When the current location of the terminal indicated by the E-RAB Modification Indication is the LTE coverage,
A method for controlling bandwidth in a wireless access system, including a case in which the terminal moves from a new radio (NR) coverage corresponding to a 5G base station to the LTE coverage. The method of claim 1,
Regardless of the location of the terminal, an IP Multi-Media Subsystem (IMS) session is maintained between the SPGW and the 4G base station. HSS (Home Subscriber Server);
Serving Gateway/PDN Gateway (SPGW);
A 4G base station for receiving an Attach Request from a specific terminal; And
When the access request is received through the 4G base station, bandwidth information (Internet APN) corresponding to the Internet session of the terminal is received from the HSS, and first bandwidth information corresponding to 4G is included in the bandwidth information obtained from the HSS. When all the second bandwidth information corresponding to 5G is present, Mobility (MME) for transmitting a Create Session Request including the second bandwidth information to the SPGW in response to an Internet session creation request for the terminal Management Entity),
The SPGW is,
After the session creation request is received, when a Modify Bearer Request including the first bandwidth information is received from the MME, the terminal is generated as an Internet session for the terminal between the SPGW and the 4G base station The traffic for the 4G is transmitted to the 4G base station by controlling the bandwidth corresponding to the 4G technology,
The first bandwidth information included in the bearer change request,
It is obtained from the HSS before the Internet session is created, the wireless access system. The method of claim 11,
The first bandwidth information is set to AMBR (Aggregated Maximum Bit Rate) type,
The second bandwidth information is set to an extended AMBR type. The method of claim 12,
The bearer change request (Modify Bearer Request),
A wireless access system comprising an Internet APN information area set to the AMBR type. The method of claim 12,
The MME,
Upon receiving the E-RAB Modification Indication from the 4G base station, transmitting a bearer change request including bandwidth information corresponding to the current location of the terminal indicated by the E-RAB Modification Indication to the SPGW. The method of claim 14,
Further including a 5G base station,
When the current location of the terminal indicated by the E-RAB Modification Indication is NR (New Radio) coverage corresponding to the 5G base station,
The wireless access system, wherein the bearer change request including bandwidth information corresponding to the current location of the terminal includes an Internet APN information area set to the Extended AMBR type. The method of claim 15,
When the current location of the terminal indicated by the E-RAB Modification Indication is the NR coverage,
The wireless access system comprising a case in which the terminal attempts an initial access in the NR coverage, or the terminal moves from a Long Term Evolution (LTE) coverage corresponding to the 4G base station to the NR coverage. The method of claim 15,
As the bearer change request including bandwidth information corresponding to the current location of the terminal is transmitted to the SPGW, the Internet session between the SPGW and the 4G base station is changed to an Internet session between the SPGW and the 5G base station. The method of claim 14,
When the current location of the terminal indicated by the E-RAB Modification Indication is LTE (Long Term Evolution) coverage corresponding to the 4G base station,
The wireless access system, wherein the bearer change request including bandwidth information corresponding to the current location of the terminal includes an Internet APN information area set to the AMBR type. The method of claim 18,
When the current location of the terminal indicated by the E-RAB Modification Indication is the LTE coverage,
A radio access system including a case in which the terminal moves from NR (New Radio) coverage corresponding to a 5G base station to the LTE coverage. The method of claim 11,
Regardless of the location of the terminal, an IP Multi-Media Subsystem (IMS) session is maintained between the SPGW and the 4G base station.

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