KR102315347B1 - HSS(Home Subscriber Server) and HSS control method - Google Patents

Abstract

The present invention relates to a Home Subscriber Server (HSS) and a control method of the HSS. In the Home Subscriber Server (HSS) control method for managing IP addresses assigned to N (N is an integer greater than or equal to 2) P-GWs (Packet Data Network Gateway) according to an embodiment of the present invention, the first P-GW determining whether it is in any of a service unavailable state and a serviceable state; dividing a plurality of static IP addresses allocated to the first P-GW when the first P-GW is out of service; and matching the network identification information of the divided IP address with at least one of the second P-GW to the N-th P-GW.

Description

HSS (Home Subscriber Server) and HSS control method {HSS (Home Subscriber Server) and HSS control method}

The present invention relates to a technology for allocating a unique static IP address to a terminal (User Equipment, UE) in a Long Term Evolution (LTE) network, and in more detail, an IP address between P-GW (Packet Data Network Gateway) It's about how to succeed.

The LTE (Long Term Evolution) network is divided into an LTE part dealing with radio access network (E-UTRAN) related technologies and an EPC (Enhanced Packet Core) part dealing with core network related technologies. By integrating LTE and EPC, EPS (Enhanced Packet System) is called Since the LTE network is an E2E all-IP network, the traffic flow from the wireless link where the user terminal accesses the base station to the PDN (Packet Data Network) that connects to the final service provider operates based on IP.

When a user who purchases an LTE terminal subscribes to a mobile communication service provider-hereafter referred to as “operator”-, the user selects the service type and rate plan, and the operator configures a subscription profile based on this subscription information. control the use of services.

EPS is composed of a plurality of network entities that perform given functions in order to provide a wireless connection to a mobile terminal (mobile terminal). For example, a Packet data network (PDN)-Gateway (P-GW) may connect the core network to an external packet data network (PDN) such as the Internet. In other words, the P-GW may serve as an IP anchor point for Internet Protocol (IP) traffic delivered through the P-GW.

On the other hand, a situation may arise in which a change of the P-GW connected to the UE (User Equipment) is required for IP traffic offload, effective use of IP resources, and fast LTE network service provision through smoother path selection. In this situation, when the P-GW is changed, the ongoing IP traffic may be terminated, which may cause service disruption to the user.

In this regard, in the 3GPP interworking standard (23.401), when a UE (User Equipment) attaches to a wireless access network, the subscriber's static IP address and the associated P-GW address are provided through the Home Subscriber Server (HSS). specified to be assigned. However, standards or related technologies for specific methods and procedures for the succession of static IP addresses between P-GWs have not been published and defined.

Therefore, there is a need for a specific method for managing IP addresses allocated between P-GWs and enabling subscribers to use LTE network services smoothly by faster succession (addition or deletion) of IP addresses allocated to P-GWs.

An embodiment is designed to solve the problems of the prior art, and an object of the present invention is to provide a Home Subscriber Server (HSS) and a control method of the HSS.

In detail, one embodiment is such that, when the P-GW serving as an IP anchor has a failure in providing LTE network services, the UE assigned a fixed IP address serviced through the corresponding P-GW is serviced through another P-GW. Provides a method of controlling HSS (Home Subscriber Server) and HSS that automatically succeeds between P-GWs with static IP addresses.

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

In order to solve the above technical problem, a Home Subscriber Server (HSS) that manages IP addresses assigned to N (N is an integer greater than or equal to 2) P-GW (Packet Data Network Gateway) according to an embodiment of the present invention The control method includes the steps of: determining whether the first P-GW is in any of a service unavailable state and a serviceable state; dividing a plurality of static IP addresses allocated to the first P-GW when the first P-GW is out of service; and matching the network identification information of the divided IP address to at least one of a second P-GW to an N-th P-GW; may include.

According to an embodiment, the dividing may include dividing the plurality of static IP addresses allocated to the first P-GW in proportion to the usage of the IP pool of the second P-GW to the N-th P-GW. differential partitioning; may include.

According to an embodiment, the dividing may include: equally dividing a plurality of static IP addresses allocated to the first P-GW into the N-1 numbers; may include.

According to an embodiment, the matching may include: transmitting a message including the matched network identification information to at least one of the second P-GW to the N-th P-GW; may further include.

According to an embodiment, in the matching step, at least one of the second P-GW to the N-th P-GW adds the matched network identification information, and the matched network identification information to a router transmitting a message including information; may further include.

According to an embodiment, the matching may include one of the second P-GW to the N-th P-GW when an attach request of a terminal belonging to the IP address assigned to the first P-GW is requested. transmitting the matched address of the P-GW to a Mobility Management Entity (MME); may further include.

according to an embodiment, when the first P-GW is in a serviceable state, recovering the equally divided network identification information from the second P-GW to the N-th P-GW; may further include.

According to an embodiment, the recovering includes identifying the matched network with at least one of a plurality of divided static IP addresses of the first P-GW among the second P-GW to the N-th P-GW. requesting deletion of information; transmitting the deleted network identification information to the first P-GW for rematching; may include.

According to an embodiment, in the recovering, at least one of the plurality of divided static IP addresses of the first P-GW among the second P-GW to the N-th P-GW is matched by a router transmitting a message requesting deletion of the matched network identification information to may further include.

According to an embodiment, the recovering may include: transmitting, by the first P-GW, a message including the re-matched network identification information to a router; may include.

According to an embodiment, transmitting the address of the first P-GW to the MME when an attach request of a terminal corresponding to the IP address retrieved to the first P_GW is requested; may further include.

According to an embodiment, the determining may include: transmitting a status check message to the N P-GWs every preset period; may include.

According to an embodiment, the present invention may provide a computer-readable recording medium in which a program for executing the above-described method is recorded.

In addition, the Home Subscriber Server (HSS) managing the IP addresses allocated to the N P-GWs (Packet Data Network Gateways) according to an embodiment of the present invention transmits a status check message to the N P-GWs every preset period. a communication unit that transmits to the GW; and a control unit that determines whether the first P-GW is in either a service unavailable state or a serviceable state from a response message to the status check message. wherein, if the first P-GW is out of service, the controller divides a plurality of static IP addresses allocated to the first P-GW, and sets the network identification information of the divided IP address to the second P- It can match at least one of the GW to the N-th P-GW.

According to an embodiment, the control unit divides the plurality of static IP addresses allocated to the first P-GW proportionally and differentially according to the usage of the IP pool of the second P-GW to the N-th P-GW. can do.

According to an embodiment, the controller may equally divide the plurality of static IP addresses allocated to the first P-GW into the N-1 numbers.

According to an embodiment, the control unit may transmit a message including the matched network identification information to each of the second P-GW to the N-th P-GW by the communication unit.

According to an embodiment, the control unit is configured to perform an Attach Request from a terminal belonging to the IP address allocated to the first P-GW, among the second P-GW to the N-th P-GW by the communication unit. The address of the P-GW matched with any one may be transmitted to a Mobility Management Entity (MME).

According to an embodiment, if the first P-GW is in a serviceable state, the control unit may transmit the equally divided network identification information of the first P-GW among the second P-GW to the N-th P-GW. A plurality of divided static IP addresses may be retrieved from at least one matched.

According to an embodiment, the control unit is configured to match at least one of the plurality of divided static IP addresses of the first P-GW among the second P-GW to the N-th P-GW by the communication unit. A message requesting deletion of the deleted network identification information may be transmitted, and the deleted network identification information may be transmitted to the first P-GW.

According to an embodiment, the control unit may transmit the address of the first P-GW to the MME by the communication unit when the terminal corresponding to the IP retrieved to the first P_GW makes an attach request.

The effects of the HSS (Home Subscriber Server) and the HSS control method according to the present invention will be described as follows.

First, in the present invention, by monitoring the status of the P-GW by the HSS managing the IP address assigned to the P-GW, it is possible to quickly detect whether there is a failure in a specific P-GW.

Second, in the present invention, when a failure occurs for a specific P-GW, for a terminal receiving LTE network service by the corresponding P-GW, the static IP set in the corresponding terminal is automatically inherited to another P-GW, so that it is faster After that, IP traffic can proceed.

The effects obtainable in the present invention are not limited to the above-mentioned effects, and other effects not mentioned may be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description. will be.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings are provided to help understanding of the present invention, and provide embodiments of the present invention together with detailed description. However, the technical features of the present invention are not limited to specific drawings, and features disclosed in each drawing may be combined with each other to form a new embodiment.
1 is an LTE network configuration diagram to help understand the present invention.
2 is a diagram for explaining a traffic flow on an LTE network to help the understanding of the present invention.
3 is a diagram for explaining a method of allocating an IP address in an LTE network to help the understanding of the present invention.
4 is a diagram for explaining an IP address allocation procedure for helping understanding of the present invention.
5 is a flowchart illustrating a P-GW change method by a router and an HSS according to an embodiment of the present invention.
6 is a diagram for explaining a method of matching by automatically changing a P-GW by the HSS according to an embodiment of the present invention.
7 is a diagram for explaining a method of recovering an IP address matched to a P-GW by the HSS according to an embodiment of the present invention.
8 is a structural diagram illustrating a method for receiving state information of a P-GW by an HSS according to an embodiment of the present invention.
9 is a diagram for explaining a method of dividing an IP address when the first P-GW is in a service outage state according to an embodiment of the present invention.
10 is a diagram for explaining a method of recovering an IP address when the first P-GW is in a serviceable state according to an embodiment of the present invention.
11 is a flowchart illustrating a method of matching by automatically changing a P-GW by an HSS according to an embodiment of the present invention.
12 is a structural diagram for explaining an HSS, which is 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 "part" for the components used in the following description are given or mixed in consideration of only the ease of writing the specification, and do not have a meaning or role distinct from each other by themselves.

In the description of the present invention, if it is determined that the subject matter of the present invention may be unnecessarily obscured as it is obvious to those skilled in the art with respect to related known techniques, the detailed description thereof will be omitted.

In one embodiment, in order for a subscriber to provide a smooth LTE network service by a change of the P-GW, a fixed IP address assigned to each subscriber and network identification information (eg, a prefix) in the IP address are linked to the P-GW (Packet) Describes the operation details of HSS (Home Subscriber Server) that manages Data Network (PDN)-Gateway) information and P-GW that serves as an anchor of IP address in LTE EPC. That is, an embodiment relates to a P-GW and a Home Subscriber Server (HSS) that manages IP addresses assigned to the P-GW.

1 to 4 describe a general LTE network and a network entity included in the network, and in FIGS. 5 to 12 , a detailed method for the HSS to inherit IP between P-GWs is described.

1 is an LTE network configuration diagram according to the present invention.

Referring to Figure 1, referring to Figure 1, the LTE network UE (User Equipment, 10), eNB (Evolved Node B, 20), S-GW (Serving Gateway, 30), P-GW (Packet Data Network (P-GW) ( PDN)-Gateway, 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) may be configured to include.

The UE 10 is an LTE user terminal and is connected to the eNB 20 through the LTE Uu air interface 15 . Here, the LTE Uu interface 15 is a wireless interface, and a control plane for transmitting and receiving control messages and a user plane for providing user data are defined.

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.

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

The P-GW 40 connects the UE 10 with an external Packet Data Network (PDN) 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 Policy and Charging Control (PCC) rule from the PCRF 100, applies it to the corresponding service flow, and provides a charging function for each UE 10/SDF (Service Date Flow). do.

The MME 50 is a mobility management entity of E-UTRAN, and communicates with the HSS 60 for user authentication and user profile download, and provides EPS mobility management (EMM) and EPS Session management (ESM) to the user terminal through NAS signaling. function is provided. In detail, the MME 50 is a node that handles the control plane in the EPC, manages connection and release of an EPS radio bearer to the terminal, and performs authentication, security key management, paging, IP address assignment of the terminal, etc. do. An Evolved Packet System (EPS) may include an LTE radio access network (E-UTRAN) and an LTE core network (EPC).

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

In one embodiment, the HSS 60 manages the IP address allocated to the UE 10 by the P-GW 40, and whether the P-GW 40 is in a serviceable state (In-Service) or out of service state ( Out-of-Service) can be managed. The HSS 60 may check the usage of the IP pool allocated to the P-GW 40 as well as the state of the P-GW 40 .

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 data record (CDR)-based charging information.

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

The PCRF 100 is an entity that performs policy and charging control, and provides policy control decision and charging control functions. The PCC rule generated in the PCRF 100 is transmitted to the P-GW 40 .

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. In this case, GTP tunneling per bearer is provided.

S5 35 is an interface between the S-GW 30 and the P-GW 40, and provides a control plane and a user plane. In this case, 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 . In the user plane, an IETF-based IP packet forwarding protocol is used, and in the control plane, protocols such as DHCP and RADIUS/Diameter are used.

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

X2 65 is an interface between two eNBs 20 and provides a control plane and a user plane. In the control plane, the X2-AP protocol is used, and in the user plane, GPRS Tunneling Protocol (GTP) tunneling is provided per bearer for data forwarding during X2 handover.

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

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

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

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

2 is a diagram for explaining a traffic flow on an LTE network to help the understanding of the present invention.

In more detail, Figure 2 shows the Internet traffic flow in the user plane of the LTE network reference model. Reference numeral 200a denotes a traffic flow from the UE 10 to the Internet - hereinafter referred to as "uplink traffic flow" - and reference numeral 200b denotes a traffic flow from the Internet to the UE 10 - hereinafter referred to as "downlink traffic flow" business card- indicates.

IP packets are transmitted through GTP tunnels on the S1-U (25) and S5 (35) interfaces, respectively. Here, the GTP tunnel is established for each EPS bearer through control signaling when the UE 10 initially accesses the LTE network.

Since several EPS bearers are configured on one S1-U (25) and S5 (35) interfaces, Tunnel Endpoint Identifiers (TEIDs) are assigned to uplink and downlink when establishing each GTP tunnel to distinguish them. When a GTP tunnel is established in the S1-U(25) interface, a TEID (UL S1-TEID) having an endpoint is allocated to the S-GW 20 upwardly, and a TEID (DL S1) having an endpoint to the eNB 20 downwardly. -TEID) is assigned. Similarly, when a GTP tunnel is established in the S5 (35) interface, a TEID having an endpoint in the P-GW 40 upward (UL S5-TEID) and a TEID having an endpoint in the S-GW 30 in the downward direction (DL S5-TEID) is assigned.

When the user IP packet is transmitted through the GTP tunnel on the S1-U (25) and S5 (35) interfaces, the eNB 20, the S-GW 30 and the P-GW 40 attach the GTP tunnel to the GTP packet header. TEID allocated at creation is inserted and transmitted. The S-GW 30 must have mapping information between UL S1-TEID and UL S5-TEID in order to terminate the S1-GTP tunnel in the uplink and transmit a user IP packet to the S5-GTP tunnel. Similarly, in the downlink, mapping information between DL S5-TEID and DL S1-TEID must be maintained.

Hereinafter, a procedure in which each entity processes uplink and downlink Internet traffic flows will be described in detail with reference to FIG. 2 .

First, in the uplink, the UE 10 transmits an internally generated user IP packet to the eNB 20 through the LTE-Uu 15 interface. The eNB 20 configures the S1 GTP header with the S-GW IP address as the destination address, the eNB 20 address as the source address, and the UL S1-TEID as the TEID, and adds it to the received user IP packet through the S1 GTP tunnel. It is transmitted to the S-GW (30).

When the S-GW 30 receives the user IP packet through the S1 GTP tunnel, S5 sets the P-GW 40 IP address as the destination address, the S-GW 30 as the source address, and the UL S5-TEID as the TEID. Configure GTP headers. Thereafter, the configured S5 GTP header is added to the user IP packet and transmitted to the P-GW 40 through the S5 GTP tunnel.

Subsequently, the P-GW 40 extracts the user IP packet by controlling the S5 GTP header and transmits it to the Internet through IP routing.

Looking at the downlink traffic flow, the P-GW 40 receives a user IP packet directed to the UE 10 through the Internet. The P-GW 40 adds an S5 GTP header consisting of the S-GW IP address as the destination address, the P-GW IP address as the source address, and DL S5-TEID as the TEID to the user IP packet, and then through the S5-GTP tunnel. It is transmitted to the S-GW (30).

The S-GW 30 adds the S1 GTP header consisting of the eNB IP address as the destination address, the S-GW IP address as the source address, and the DL S1-TEID as the TEID to the user IP packet received through the S5 GTP tunnel. It is transmitted to the eNB 20 through the GTP tunnel.

The eNB 20 transmits the user IP packet from which the S1 GTP header is removed to the UE 10 through a data radio bearer (DRB), which is a bearer on the radio link.

It should be noted that the GTP tunnel of FIG. 2 is a user plane GTP tunnel for transmitting user IP packets - hereinafter referred to as a "GTP-U tunnel".

3 is a diagram for explaining a method of allocating an IP address in an LTE network to help the understanding of the present invention.

In detail, FIG. 3 relates to a method in which the LTE network allocates an IP address to the user terminal when the user terminal accesses the LTE network in the LTE network, and a dynamic IP address allocation method, which is a representative IP address allocation method. and a static IP address allocation method.

In general, when the UE 10 initially accesses the LTE network, it requests the PDN 110 connection to the LTE network. In order to provide the PDN 110 connection to the UE 10 , the P-GW 40 allocates an IP address to be used by the UE 10 - that is, a PDN address - and delivers it to the UE 10 . Here, the PDN address is transferred from the P-GW 40 to the UE 10 in the process of establishing a default bearer between the P-GW 40 and the UE 10, and the UE 10 is the PDN. A service provided by the PDN 110 may be accessed using the address.

In this case, the P-GW 40 allocates an IP address to the UE 10 includes a dynamic IP address allocation method that is dynamically generated whenever the UE 10 accesses the LTE network, and an IP allocated when the user subscribes to the service. When the UE 10 accesses the LTE network, there may be a static IP address assignment method in which the address is provided with reference to the subscriber profile stored in the HSS 60 .

In more detail, the dynamic IP address allocation method is as shown in FIG. 3 , when the operator configures an IP pool in the P-GW 40 in advance and then the UE 10 accesses the LTE network, the IP pool Dynamically assign an IP address by referring to .

On the other hand, in the static IP address allocation method, when the user joins the operator network, the operator allocates an IP address to be used permanently to the UE 10 and maintains it in the HSS 60, and when the UE 10 accesses the LTE network, P -GW (40) receives the IP address corresponding to the UE (10) from the HSS (60) and transmits the IP address to the UE (10).

The UE 10 may request predetermined protocol information related to an external protocol and an application by using a Protocol Configuration Option (PCO) parameter in a process of requesting a PDN connection when initially accessing the LTE network. Here, the protocol information may include a DNS server address.

For details on the PCO described above, reference will be made to the contents disclosed in 3GPP TS 24.008.

4 is a diagram for explaining an IP address allocation procedure for helping understanding of the present invention. In more detail, FIG. 4 is a diagram for explaining a static IP address allocation procedure.

Referring to FIG. 4 , the UE 10 transmits a PDN Connectivity Request Message to the MME 50 when power is applied (Power On) (S401). In this case, the PDN connection request message may include information such as International Mobile Station Identity (IMSI), PDN type=IPv4, PCO=DNS Server IPv4 Address Request. Here, the IMSI is unique identification information for identifying a subscriber within the LTE network.

The MME 50 transmits a Location Update Request Message including the IMSI to the HSS 60 (S403).

The HSS 60 inquires a subscriber profile corresponding to the IMSI from an internal database and transmits a Location Update Answer Message including a static IP address pre-allocated to the corresponding subscriber to the MME 50 (S405) .

MME 50 is a static IP address received from the HSS 60 and IMSI (International Mobile Subscriber Identity) received from the UE 10, PDN type = IPv4, PCO = session creation request including DNS Server IPv4 Address Request, etc. A message (Create Session Request Message) is transmitted to the S-GW 30 (S407).

Subsequently, the S-GW 30 transmits the received session creation request message to the P-GW 40 (S409).

Thereafter, in response to the request messages in steps 409 and 407, the P-GW 40 and the S-GW 30 send a Create Session Response Message to the MME 50, respectively. send. Here, the session creation response message may include the static IP address in the PDN address field and the DNS server IP address requested by the user in the PCO field.

MME 50 is the default EPS bearer activation request message including the static IP address and DNS IP address, where the DNS IP address may include a primary DNS IP address and a secondary DNS IP address (Activate Default EPS Bearer Context Request) ) to the UE 10 (S415). Here, the default EPS bearer activation request message, which is one of the EPS session management messages - hereinafter referred to as "ESM (EPS Session Management) messages" - is an EPS mobility management message - hereinafter. “EMM (EPS Mobility Management) message” may be included in the business card-in Attach Accept Message and delivered.

Thereafter, the static IP address and DNS IP address are stored in the internal memory of the UE 10 (S417), and a default EPS bearer is established between the UE 10 and the P-GW 40 (S419). In this case, the UE 10 may access the PDN 110 through the configured default EPS bearer to transmit/receive user IP packets.

Hereinafter, we will briefly review policy and charging control in LTE networks.

PCRF 100 determines a PCC rule for each service data flow (SDF: Service Data Flow), and uses the determined PCC rule through the Gx 85 interface (Policy and Charging Enforcement Function)-for example, P-GW ( 40) - to pass on. Here, the PCC rule may be determined based on operator policy - for example, including a QoS policy, gate status, and a charging method. In addition, the PCC rule may include information on detection of a packet belonging to a specific SDF, identification of a service, charging parameters to be applied to the SDF, and policy control for the SDF.

The PCRF 100 generates a predetermined packet filter - for example, an SDF template - for detecting which SDF the user IP packets transmitted/received on the SGi 45 interface correspond to, and uses this as a PCC rules can be applied. In addition, the P-GW 40 may bind the SDF QoS and LTE bearer QoS using the PCC rule received from the PCRF 100 and then reflect it in the EPS bearer.

Here, the SDF template is included in the PCC rule. SDF template consists of Source IP Address, Destination IP Address, Source Port, Destination Port, and Protocol Identifier for each uplink and downlink. It is a 5-tuple-based SDF delimiter (Classifire).

In general, a plurality of IP flows - or also called "service flows" - may exist according to an application service used by one UE or a type of traffic transmitted and received. For example, the application service may include Naver connection, Daum connection, KakaoTalk, game, VoIP, YouTube, and the like. These IP flows can be mapped to SDF using 5-tuple based SDF template. As described above, when multiple IP flows are classified on a 5-tuple basis and mapped to an SDF, the P-GW 40 may process QoS for each SDF and then map the corresponding SDF to the EPS bearer.

5 is a flowchart illustrating a P-GW change method by a router and an HSS according to an embodiment of the present invention.

Referring to FIG. 5 , when a plurality of P-GWs are included in an LTE network, a fixed IP address prefix designated for each of the plurality of P-GWs may be accommodated.

In one embodiment, the first P-GW 510 in the LTE network is an external router (eg, PDN) for the UE assigned a static IP address including the network identification information of a:b:c::/48 ) can be connected to

The IP address may include network identification information and host identification information. As an embodiment, the network identification information may have 48 bits according to IPv6. Preferably, the network identification information may be a prefix.

The first P-GW 510 may receive IP traffic having a:b:c::/48 as network identification information from the router 530 and may deliver it to the UE via the S-GW. In one embodiment, router 530 may be a PDN. In other words, the first P-GW 510 is servicing IP traffic to a UE assigned a static IP address having a prefix of a:b:c::/48, and the router 530 directs the traffic to the first P-GW. It can route to GW 510 .

On the other hand, when the first P-GW 510 is out of service (Out-of-Service), traffic processing for band a:b:c::/48 becomes impossible.

In this situation, the HSS 540 sets the P-GW configuration corresponding to the IP traffic by the static IP address having the prefix a:b:c::/48 from the existing first P-GW 510 to the second P- You need to manually change to GW (520).

With the change of the HSS 540 , even in the router 530 , rather than the first P-GW 510 , next-hop transmission to a static IP address having a prefix of a:b:c::/48 can be performed. The setting must be changed to the second P-GW 520 .

Thereafter, when the UE assigned a static IP address having a corresponding prefix of a:b:c::/48 makes an attach request to the wireless network network, the HSS 540 sends a location update request message from the MME. Update Request Message), the response is changed to the IP information of the second P-GW 520 instead of the IP information of the first P-GW 510 in response (Location Update Answer).

Accordingly, the UE to which the static IP address having the prefix a:b:c::/48 is assigned can access the wireless network through the second P-GW 520 and receive the LTE network service.

As a result, when the first P-GW 510 is in an out-of-service state, in order to succeed the fixed IP address prefix connected to the wireless network to another P-GW, the HSS 530 And it is necessary for the operator of the router 540 to perform a setting operation for changing the setting of the P-GW.

However, this manual succession method may have several limitations. The operator must continuously monitor the status of the P-GW, and if a specific P-GW is out of service, the operator needs to know the procedure to respond to the monitoring result, and the Due to time, subscribers may feel inconvenience. Overall, the manual succession method may have limitations in terms of operational inefficiency. In order to overcome the above limitation, a method in which IP succession between P-GWs is automatically performed by the HSS will be described in FIGS. 6 to 12 .

6 is a diagram for explaining a method of matching by automatically changing a P-GW by the HSS according to an embodiment of the present invention.

Referring to FIG. 6, depending on whether the P-GW is in an out-of-service state, the HSS 640 and the P- The operation of the GWs (the first P-GW 610 to the N-th P-GW 620 (N is an integer of 2 or more)) will be described in detail.

The HSS 640 includes static IP address prefix information mapped to each of the first P-GW 610 to the N-th P-GW 620 and the first P-GW 610 to the N-th P-GW 620 . status can be monitored. In addition, the HSS 640 may check the usage of the IP pool allocated to each of the first P-GW 610 to the N-th P-GW 620 .

The HSS 640 stores a mapping table in which the identification number of the P-GW (eg, the first P-GW, the second P-GW, etc.) and the static IP address information allocated to the P-GW are matched in the memory. can be saved The mapping table will be described with reference to FIGS. 9 and 10 .

Each of the P-GWs 610 to 620 may be in an Out-of-Service or In-Service state, and the HSS 640 is the state of the P-GWs 610 to 620. can manage

The HSS 640 may transmit a status check message every preset period, and receive a response message to determine the status of the P-GWs 610 to 620 .

When the state of the first P-GW 610 is recognized as an out-of-service state, the HSS 640 maps a fixed IP address prefix per a plurality of P-GWs 610 to 620 it manages. Among the information, the fixed IP address prefix of the first P-GW 610 may be divided into at least one of the second P-GW to the N-th P-GW 620 to be matched.

In one embodiment, the HSS 640 uses a plurality of static IP address prefixes assigned to the first P-GW 610 to be used in the IP pool of the second P-GW to the N-th P-GW 620 . can be divided proportionally and differentially. In addition, the HSS 640 may divide and match the static IP address prefix only to some P-GWs, except for P-GWs whose IP pool usage is equal to or greater than a preset value. Alternatively, the HSS 640 may equally divide the plurality of static IP address prefixes allocated to the first P-GW 610 into the N-1 numbers.

When the state of the first P-GW 610 is recognized as the serviceable state (In-Service), the HSS 640 divides it into at least one of the second P-GW to the N-th P-GW 620 and matches it The fixed IP address prefix may be retrieved as a list of the mapping table of the first P-GW 610 . This will be described in detail with reference to FIG. 7 .

The HSS 640 may transmit a message to notify each of the changed mapping information to at least one of the second P-GW to the N-th P-GW 620 in which information in the mapping table of the static IP address prefix is changed.

At least one of the second P-GW to the N-th P-GW 620 that has received a message on whether to add or delete a static IP address prefix from the HSS 640 receives the corresponding static IP address by the router 630 . An ICMPv6 Router Advertisement (RA) message containing the corresponding static IP address prefix information may be transmitted to the router 630 to effectively update the route of the prefix traffic.

Through this process, in the structure of operating a fixed IP address prefix designated per P-GW (610 to 620), when a situation occurs in which the static IP address prefix of the corresponding PGW must be succeeded to another PGW due to a specific P-GW failure, etc. As the P-GW setting can be changed automatically by the HSS 640 instead of the manual succession method by the operator, rapid failure response and operational convenience can be improved.

7 is a diagram for explaining a method of recovering an IP address matched to a P-GW by the HSS according to an embodiment of the present invention.

Referring to FIG. 7 , IP traffic for a static IP address having a prefix of a:b:c::/48 is divided into the second P-GW to the Nth P-GW 730 to receive LTE network service. am.

In this situation, the HSS 750 may recognize that the state of the first P-GW 710 is in-service. As shown in FIG. 6 , the HSS 750 transmits a status check message to the first P-GW 720 , and through a response message to this, the status of the 1 P-GW 710 is displayed as a serviceable state (In- service) can be recognized.

The HSS 750 may recover a static IP address having a prefix a:b:c::/48 originally provided by the first P-GW 720 in a serviceable state. A method of recovering an IP address will be described in detail with reference to FIG. 10 . When the first P-GW 720 returns to the serviceable state, traffic of other P-GWs can be alleviated to effectively use IP resources.

Thereafter, the HSS 750 performs an attach request when a subscriber belonging to a fixed IP address having a prefix a:b:c::/48 provided by the first P-GW 720 in a serviceable state requests an attachment. In response to the update request message (Location Update Request) from the MME (Location Update Answer), the P-GW information is responded to the IP information of the first P-GW (510).

The HSS 750 is the first P-GW 720 is distributed to at least any one of the second P-GW to the N-th P-GW to which the IP address was added in the service outage state of the IP address prefix that was distributed and added. A deletion may be requested. The request may include a control command instructing deletion of the distributed static IP address prefix and a static IP address prefix to be deleted.

Thereafter, the HSS 750 receives a message including a static IP address having a prefix a:b:c::/48 to be serviced to the first P-GW 720 whose state is changed to the serviceable state (IN-Service). can be transmitted. The message may include a control command for instructing addition of an IP address of a prefix of a:b:c::/48 and a fixed IP address prefix to be added to the first P-GW 720 .

At least one of the second P-GW to N-th P-GW 730 that has received the static IP address prefix to be deleted sends the ICMPv6 Router Advertisement to the router 740 so that the corresponding static IP address prefix is no longer routed to itself. (RA) messages can be sent. The RA message may include the fixed IP address prefix received in the Prefix information of the ICMPv6 Option field, and the Valid Lifetime field may be written as 0 to prevent routing to itself.

The first P-GW 720 that has received the static IP address prefix to be serviced may transmit an ICMPv6 Router Advertisement (RA) message to the router 740 so that the corresponding static IP address prefix can be routed thereto. The RA message may include the fixed IP address prefix received in Prefix information of the ICMPv6 Option field.

The HSS 750 targets the UE belonging to the static IP address prefix retrieved by the first P-GW 720 in order to induce the Evolved Packet System (EPS) session of the UE to be reset to the first P-GW 720. Cancel Location Request may be transmitted to the MME connected to the UE. Thereafter, the MME may request reconnection by transmitting a Location Update Request Message including the IMSI to the HSS 750 again.

Accordingly, the fixed IP address having the prefix a:b:c::/48 enables LTE network service again to the first P-GW 720 restored to the serviceable state.

8 is a structural diagram illustrating a method for receiving state information of a P-GW by an HSS according to an embodiment of the present invention.

Referring to FIG. 8 , the HSS 830 may monitor the state of the P-GW 820 managed by the HSS 830 .

As a specific monitoring method, the HSS 830 may transmit a periodic status check message and perform monitoring through a response message thereto. In another embodiment, a method by a separate setting by the operator of the HSS 830 is have.

For example, the operator of the HSS 830 may check the status of the HSS 830 by utilizing ICMP-Ping.

As another embodiment, while using both of the two methods, it is possible to set a method as a criterion to which the priority of the state determination is given among the two methods.

9 is a diagram for explaining a method of dividing an IP address when the first P-GW is out of service according to an embodiment of the present invention, and FIG. 10 is an embodiment of the present invention for the first P-GW. It is a diagram for explaining a method of recovering an IP address when the GW is in a serviceable state.

9 and 10 illustrate a method of dividing and matching an IP address and a method of recovering a divided and matched IP address.

The P-GW may be determined by the HSS to be in either a serviceable state or an out-of-service state. In one embodiment, there may be 5 P-GWs managed by the HSS.

When the P-GW is in a serviceable state, it may have a mapping table of a static IP address prefix, a P-GW address before the change, and a P-GW address after the change, as shown in FIG. 9A . By (a), the first P-GW may provide a service for at least one UE having a static IP address having a prefix of a:b:c::/48.

In an embodiment, the HSS may evenly distribute and match a static IP address having a prefix of a:b:c::/48 to the second P-GW to the fifth P-GW.

The usage of the IP pool for each of the second P-GW to the fifth P-GW is the same, or the preset congestion amount is exceeded even when IP addresses are distributed to all of the second P-GW to the fifth P-GW If not, the HSS may equally distribute the IP address to the second P-GW to the fifth P-GW to match.

Referring to FIG. 9B , the HSS may add a prefix of 2 bits to divide a:b:c::/48 into the second P-GW to the fifth P-GW and use it. In other words, only 2 bits can be used to identify four P-GWs. According to an embodiment, the number of digits of the prefix may be increased according to the number of P-GWs managed by the HSS.

As a specific example, the address notation of IPv6 using a hexadecimal number is a:b:c:0000:/50 for IP address prefixes for identifying P-GWs from the second P-GW to the fifth P-GW, respectively. , a:b:c:4000:/50, a:b:c:8000:/50, a:b:c:c000:/50. There are 2^16 IP addresses with a:b:c::/48 as a prefix, and each of the 2nd P-GW to the 5th P-GW will receive an additional 2^14 divided IP addresses. can be

Referring to (a) of FIG. 10 , the first P-GW is recognized as out of service, so that each of the second P-GW to the fifth P-GW is a:b:c:0000:/48, a:b: It provides LTE network services by receiving IP addresses for c:4000:/48, a:b:c:8000:/48, and a:b:c:c000:/48.

Thereafter, when the HSS recognizes the state of the first P-GW as a serviceable state, the divided IP address is retrieved. HSS contains the ranges a:b:c:0000:/50, a:b:c:4000:/50, a:b:c:8000:/50, a:b:c:c000:/50 It can be merged into a:b:c::/48 and re-matched back to the first P-GW.

11 is a flowchart illustrating a method of matching by automatically changing a P-GW by an HSS according to an embodiment of the present invention.

Referring to FIG. 11 , the HSS may determine whether the first P-GW is in any of a service unavailable state and a serviceable state ( S1110 ).

The HSS can manage the service state of the P-GW, and according to an embodiment, transmits a state check message every preset period, and receives a response message to determine whether the service state of the P-GW is in the serviceable state ( Out-of-Service or In-Service) can be determined. In another embodiment, the HSS may determine the state of the P-GW by the operator's state test, and may set a method that is a priority criterion for determining the state in advance by prioritizing one of the two methods.

When the first P-GW is out of service, the HSS may split a plurality of static IPs allocated to the first P-GW (S1120).

The HSS may manage mapping information in which a fixed IP address prefix allocated to each of a plurality of P-GWs is matched.

When the HSS recognizes that the state of the first P-GW is changed from the serviceable state (In-Service) to the out-of-service state (Out-of-Service), fixed matching to the first P-GW in the managed mapping information The IP address prefix may be re-matched to at least one of the other N-1 P-GWs.

With respect to the partitioning method, the HSS can be evenly redistributed and matched to other P-GWs except for the first P-GW, and distributed to some P-GWs among other P-GWs except for the first P-GW. Matching may be performed, and matching may be performed by differentially distributing according to the IP pool usage of other P-GWs except for the first P-GW.

The HSS may match the prefix of the equally divided IP to at least one of the second P-GW to the N-th P-GW (S1130).

The HSS may transmit a message including a prefix matched to at least one of the second P-GW to the N-th P-GW (S1140).

When information in the mapping table managed by the HSS is changed, the HSS may transmit a message including information on IP addresses added to P-GWs whose information in the mapping table is changed.

The P-GWs receiving the message may transmit a message corresponding to the indication to the router. In other words, P-GWs that have received a message indicating addition or deletion of a static IP address prefix from the HSS may transmit an ICMPv6 Router Advertisement (RA) message to the router.

The RA message may include the received static IP address prefix in the Prefix information of the ICMPv6 Option field, and may include 0 in the Valid Lifetime Field when the static IP address prefix is retrieved.

12 is a structural diagram for explaining an HSS, which is an embodiment of the present invention.

Since the components shown in FIG. 12 are not essential, the HSS 1200 having more or fewer components may be implemented.

The communication unit 1210 may receive IP traffic from a router or transmit/receive a control signal from another entity in an LTE network.

In an embodiment, the communication unit 1210 may transmit a status check message to the N P-GWs at every preset period.

The controller 1220 may perform data processing and operation to control the HSS 1200 .

As an embodiment, the controller 1220 may determine whether the P-GW is in any of a service disabled state and a serviceable state from a response message to the state check message by the P-GW. In addition, if the P-GW is out of service, the controller 1220 divides a plurality of static IP addresses allocated to the corresponding P-GW, and transfers network identification information of the divided IP address to a P-GW other than the corresponding P-GW. can be matched.

The memory 1230 is a generic name for a space and/or storage area in which a predetermined program code for controlling the overall operation of the HSS 1200 and data input/output when an operation by the program code is performed is stored, It is provided in the form of EEPROM (Electrically Erasable and Programmable Read Only Memory), FM (Flash Memory), and Hard Disk Drive.

As an embodiment, the memory 1230 may store a mapping table including a P-GW managed by the HSS 1230 and a static IP address assigned to the P-GW.

The method according to the above-described embodiment may be produced as a program to be executed by a computer and stored in a computer-readable recording medium. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape. , floppy disks, and optical data storage devices.

The computer-readable recording medium is distributed on networked computer servers, so that the computer-readable code can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the above-described method can be easily inferred by programmers in the technical field to which the embodiment belongs.

It is apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

Accordingly, the above detailed description should not be construed as restrictive in all respects but as exemplary. The scope of the present invention should be determined by a reasonable interpretation of the appended claims, and all modifications within the equivalent scope of the present invention are included in the scope of the present invention.

Claims (21)

In the Home Subscriber Server (HSS) control method for managing IP addresses assigned to N (N is an integer greater than or equal to 2) P-GW (Packet Data Network Gateway),
determining whether the first P-GW is in any of a service unavailable state and a serviceable state;
dividing a plurality of static IP addresses allocated to the first P-GW when the first P-GW is out of service; and
matching the network identification information of the divided IP address to at least one of a second P-GW to an N-th P-GW;
containing,
HSS control method. According to claim 1,
The dividing step is
differentially dividing a plurality of static IP addresses allocated to the first P-GW according to the usage of the IP pool of the second P-GW to the N-th P-GW;
containing,
HSS control method. According to claim 1,
The dividing step is
equally dividing a plurality of static IP addresses allocated to the first P-GW from the second P-GW to the N-th P-GW;
containing,
HSS control method. According to claim 1,
The matching step is
transmitting a message including the matched network identification information to at least one of the second P-GW to the N-th P-GW;
further comprising,
HSS control method. According to claim 1,
The matching step is
adding, by at least one of the second P-GW to the N-th P-GW, the matched network identification information, and transmitting a message including the matched network identification information to a router;
further comprising,
HSS control method. According to claim 1,
The matching step is
When a terminal belonging to the IP address assigned to the first P-GW makes an Attach Request, the address of the P-GW matched to any one of the second P-GW to the N-th P-GW is assigned to the MME (Mobility). Management Entity);
further comprising,
HSS control method. According to claim 1,
when the first P-GW is in a serviceable state, recovering the equally divided network identification information from the second P-GW to the N-th P-GW;
further comprising,
HSS control method. 8. The method of claim 7,
The recovery step is
requesting deletion of the matched network identification information with at least one of the plurality of divided static IP addresses of the first P-GW from among the second P-GW to the N-th P-GW;
transmitting the deleted network identification information to the first P-GW for rematching;
containing,
HSS control method. 8. The method of claim 7,
The recovery step is
At least one of the second P-GW to the N-th P-GW, to which the plurality of divided static IP addresses of the first P-GW are matched, sends a router to delete the matched network identification information. sending a request message;
further comprising,
HSS control method. 9. The method of claim 8,
The recovery step is
transmitting, by the first P-GW, a message including the re-matched network identification information to the router;
containing,
HSS control method. 8. The method of claim 7,
transmitting the address of the first P-GW to the MME when an attach request of the terminal corresponding to the IP address retrieved to the first P-GW is requested;
further comprising,
HSS control method. According to claim 1,
The determining step is
transmitting a status check message to the N P-GWs every preset period;
containing,
HSS control method. A computer-readable recording medium in which a program for executing the method according to any one of claims 1 to 12 is recorded. In the Home Subscriber Server (HSS) that manages the IP addresses assigned to the N P-GW (Packet Data Network Gateway),
a communication unit for transmitting a status check message to the N P-GWs every preset period; and
a control unit that determines whether the first P-GW is in either a service unavailable state or a serviceable state from a response message to the status check message;
includes,
The control unit is
When the first P-GW is out of service, a plurality of static IP addresses allocated to the first P-GW are divided, and network identification information of the divided IP addresses is divided among the second P-GW to the N-th P-GW. matching at least one,
HSS. 15. The method of claim 14,
The control unit is
Differentially dividing the plurality of static IP addresses allocated to the first P-GW in proportion to the usage of the IP pool of the second P-GW to the N-th P-GW,
HSS. 15. The method of claim 14,
The control unit is
Equally dividing a plurality of static IP addresses allocated to the first P-GW from the second P-GW to the N-th P-GW,
HSS. 15. The method of claim 14,
The control unit is
transmitting a message including the matched network identification information to each of the second P-GW to the N-th P-GW by the communication unit;
HSS. 15. The method of claim 14,
The control unit is
When a terminal belonging to the IP address assigned to the first P-GW makes an attach request, the address of the P-GW matched with any one of the second P-GW to the N-th P-GW by the communication unit To transmit to MME (Mobility Management Entity),
HSS. 15. The method of claim 14,
The control unit is
If the first P-GW is in a serviceable state, the divided network identification information is matched with a plurality of divided static IP addresses of the first P-GW among the second P-GW to the N-th P-GW. to recover from at least one of the
HSS. 20. The method of claim 19,
The control unit is
requesting deletion of the matched network identification information with at least one of the plurality of divided static IP addresses of the first P-GW from among the second P-GW to the N-th P-GW by the communication unit sending a message,
transmitting the deleted network identification information to the first P-GW,
HSS. 20. The method of claim 19,
The control unit is
Transmitting the address of the first P-GW to the MME by the communication unit when the terminal corresponding to the IP recovered to the first P-GW makes an Attach Request,
HSS.

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