RU2652453C1 - Mobile communication system, mobility management device, method of communication, mobile communication terminal and non-time computer processable media - Google Patents

Abstract

FIELD: electrical communication engineering.

SUBSTANCE: invention relates to medium for operation transmission to a communication zone. PGW establishes a PDN connection between PWG and the mobile terminal. Subscriber information management device stores PGW ID, and PGW ID is PGW identifier. Mobility management device performs mobility management of the mobile communication terminal, and upon receipt of a tracking zone update message or a routing zone update message transmitted from the mobile communication terminal, the mobility management device transmits a message including PGW ID set therein to the subscriber information management device.

EFFECT: technical result is to provide the mobile communication terminal with a proper way to perform handover from 3GPP communication area to the non-3GPP communication area even after the subscriber information management device is restarted.

15 cl, 15 dwg

Description

FIELD OF TECHNOLOGY

[0001] The present invention relates to a mobile communication system, a mobility management device, a communication method and a program. In particular, the present invention relates to a mobile communication system, a mobility management device, a communication method and a program for performing a handover process.

BACKGROUND OF THE INVENTION

[0002] 3GPP (3rd Generation Partnership Project) explored a handoff method for seamless (ie, continuous) service provision between a communication zone using a communication method specified in 3GPP (3GPP communication zone) and a zone a communication using a communication method not specified in 3GPP (non-3GPP communication area).

[0003] A method of handover from a 3GPP communication zone to a non-3GPP communication zone, which is currently under investigation in 3GPP, is explained below. First, in the 3GPP communication area, the UE (user equipment), which is a mobile communication terminal, connects to the network where the UE is located (hereinafter referred to as the “intra-zone network”) (EPC: advanced packet core) using the 3GPP radio access method, and then connects to an external network (PDN: packet data network or Internet) through a gateway (for example, PGW: packet data network gateway). The PGW, which is the gateway for transferring (transmitting / receiving) user data related to the UE between the intra-zone network and the external network, establishes a PDN connection used to communicate with the UE. A PDN connection contains one or multiple carrier channels. A PDN connection is established for each service provided to the UE. Examples of services include services related to APN (Access Point Name), such as IMS (IP Multimedia Subsystem) and Internet Connection.

[0004] In this establishing a PDN connection in a 3GPP communication area, the MME (mobility management entity) transmits a PGW ID, which is PGW identification information, to an HSS (home subscriber server) that performs subscriber information management related to the UE. PGW ID is the PGW identification information that established the PDN connection used to communicate with the UE. An MME is a node device that performs PDN connection setup as well as mobility management and communication management related to the UE, etc. The HSS is a server device that performs control in which a PGW ID is associated with each PDN connection, and performs subscriber information management for the UE, etc. The procedure by which the MME transmits the PGW ID to the HSS is described in Non-Patent Document 1, which explains the connection procedure (ATTACH).

[0005] Then, when the UE moves to a non-3GPP communication area, the UE connects to the IP access device using the non-3GPP radio access method. The IP access device issues a request to the AAA (authentication, authorization, accounting) server about the PGW ID for the PGW, which has established a PDN connection between the PGW and the UE, so that the UE can continuously receive the service from the external network. The AAA server authenticates the communication in the non-3GPP communication zone, etc. Note that an AAA server that interacts with the HSS can capture PGW IDs that are managed in the HSS. The AAA server notifies the IP access device of the PGW ID captured from the HSS.

[0006] The IP access device may select a PGW that has established a PDN connection related to the UE using the PGW ID captured from the AAA server. In addition, the IP access device establishes a communication channel or a communication bearer between the UE and the PGW. In this way, the UE can continue to receive the service from the external network through the PGW even in the place where the UE has moved (hereinafter referred to as the “destination”). That is, a handover from a 3GPP communication zone to a non-3GPP communication zone is performed using PGW as an anchor point.

[0007] The following explains the case when a failure occurs in the HSS storing the PGW ID. When a failure occurs in the HSS, service in the HSS temporarily stops. Then, an initialization operation is performed in the HSS, and therefore, the HSS is restarted. The procedure that is performed after a restart of the HSS is described in Non-Patent Document 2. More specifically, after the restart, the HSS deletes all PGW IDs stored in the HSS. Next, the HSS sends a reset notification to the MME.

[0008] When the MME receives a reset notification from the HSS, the MME controls, i.e. records the “location information confirmed in HSS” (hereinafter also referred to as “LICH”) in the UE as “not confirmed”. Note that a state in which the LICH corresponds to “not acknowledged” indicates that the HSS is restarted and does not store the PGW ID of the PGW that established the PDN connection used to communicate with the UE.

[0009] It should be noted that in the 3GPP communication area, the UE transmits a TAU (Tracking Area Update) request message to the MME to execute the TAU as providing location information at regular intervals. After receiving the TAU request message, the MME transmits the ULR (location update request) message to the HSS in order to update the TA (tracking area) of the UE. In this process, the MME sends an ULR message to the HSS in which an active pair of attribute value (AVP) pair of access point name (APN) is set, including the PGW ID of the PGW that established the PDN connection used to communicate with the UE. The above explanation describes the case where the MME receives the TAU request message. However, the MME may transmit an ULR message to the HSS in which an active pair of attribute values (AVP) of the access point name (APN) is set, including the PGW ID of the PGW that established the PDN connection used to communicate with the UE when the MME receives the message some type other than a TAU request message.

[0010] Therefore, the HSS can re-save the remote PGW ID when associating it with the UE by receiving a ULR message in which the active AVP APN is set. In this way, the HSS can again save the PGW ID associated with the UE, even after the HSS has been restarted. Therefore, after the UE is handed over to the non-3GPP communication area, the AAA server can capture the PGW ID of the PGW that established the PDN connection used to communicate with the UE from the HSS. As a result, even in the non-3GPP communication zone, the UE can access the same PGW as the PGW accessed by the UE in the 3GPP communication zone, and therefore can perform handover using that PGW as the anchor point .

LIST OF QUOTED SOURCES

NON-PATENT DOCUMENTS

[0011] Non-Patent Document 1: 3GPP TS 23.401 V13.3.0 (2015-06), Section 5.3.2

Non-Patent Document 2: 3GPP TS 29.272 V13.2.0 (2015-06), Section 5.2.4

Non-Patent Document 3: 3GPP TS 23.402 V13.2.0 (2015-06), Section 4.3.1.2, Section 4.3.4, Chapter 16

SUMMARY OF THE INVENTION

TECHNICAL PROBLEM

[0012] The recovery procedure performed after restarting the HSS in Non-Patent Document 2, Section 5.2.4, is based on the premise that the UE performs TAU in an area that does not affect (or requires) a change in MME. More specifically, the UE transmits a TAU request message to the MME, which controls or records the LICH as “not acknowledged”. When the LICH of the UE that transmitted the TAU request message is “not acknowledged”, the MME transmits to the HSS an ULR message in which the active AVP APN is established, including the PGW ID of the PGW that established the PDN connection used to communicate with the UE.

[0013] As a recovery procedure performed after restarting the HSS, the following will explain the procedure that is performed when the UE has moved to an area that affects or requires a change in the MME. First, when the HSS restarts, the HSS sends a reset message to each MME. In response to this, each MME manages or records the LICH of the UE that is under the control of this MME at that moment, as “not acknowledged”. Then, when this UE has moved to a zone that affects the MME change, this UE transmits a TAU request message to the new MME (hereinafter also referred to as “later modified MME”). However, the later modified MME does not control, i.e. does not record the LICH of the UE that transmitted the TAU request message as “not acknowledged”. Therefore, the later modified MME does not transmit the PGW ID of the PGW that established the PDN connection used to communicate with the UE to the HSS. However, even in a case like this, a later modified MME can capture PGW ID information from the original MME (here also referred to as доMME before the change ʺ). Therefore, a later modified MME can connect to the same PGW as the PGW with which the UE was connected before moving the UE to a new zone using the captured PGW ID.

[0014] Even in a situation like this, if the UE is then handed over from the 3GPP communication zone to the non-3GPP communication zone, the AAA server cannot capture the PGW ID of the PGW that established the PDN connection used to communicate with the UE, from HSS because HSS does not store this PGW ID. Therefore, an IP access device in a non-3GPP communication area cannot detect PGW, which is used as an anchor point. Therefore, there is a problem in that the UE cannot be handed over from the 3GPP communication zone to the non-3GPP communication zone.

[0015] An object of the present invention is to provide a mobile communication system, a mobility management device, a communication method and a program to enable a UE to properly perform handover from a 3GPP communication zone to a non-3GPP communication zone even after the HSS has been restarted in the above-described situation. .

THE SOLUTION OF THE PROBLEM

[0016] A mobile communication system in accordance with a first aspect of the present invention includes: a PGW configured to establish a PDN connection used to communicate with a mobile communication terminal; An HSS configured to store a PGW ID, wherein the PGW ID is a PGW identifier; and a mobility management device configured to perform mobility management of the mobile communication terminal, wherein when the mobility management device receives a tracking zone update message transmitted from the mobile communication terminal, the mobility management device transmits a location update request message including a PGW ID set therein , to HSS regardless of the storage state of the PGW ID in the HSS.

[0017] A mobility management device in accordance with a second aspect of the present invention includes a communication unit configured to, after receiving a tracking area update message transmitted from a mobile communication terminal, transmit a location update request message including a PGW ID set to thereto, to the HSS regardless of the storage state of the PGW ID in the HSS storing the PGW ID, wherein the PGW ID is the PGW ID of that PGW that established the PDN connection used to communicate with the mobile communication terminal.

[0018] A communication method in accordance with a third aspect of the present invention includes, after receiving a tracking area update message transmitted from a mobile communication terminal, transmitting a location update request message including a PGW ID set therein to the HSS regardless of state storing the PGW ID in the HSS storing the PGW ID, wherein the PGW ID is the PGW ID of that PGW that established the PDN connection used to communicate with the mobile communication terminal.

[0019] A program in accordance with a fourth aspect of the present invention causes a computer to execute, upon receiving a tracking area update message transmitted from a mobile communication terminal, transmitting a location update request message including a PGW ID set therein to the HSS regardless of state storing the PGW ID in the HSS storing the PGW ID, wherein the PGW ID is the PGW ID of that PGW that established the PDN connection used to communicate with the mobile communication terminal.

PREFERRED SUMMARY OF THE INVENTION

[0020] According to the present invention, it is possible to provide a mobile communication system, a mobility management device, a communication method and a program allowing the UE to properly perform handover from a 3GPP communication zone to a non-3GPP communication zone even after the HSS has been restarted in the above situation.

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] FIG. 1 is a block diagram of a configuration of a mobile communication system in accordance with a first exemplary embodiment;

FIG. 2 is a block diagram of a configuration of a mobile communication system in accordance with a second exemplary embodiment;

FIG. 3 is a block diagram of an MME configuration in accordance with a second exemplary embodiment;

FIG. 4 is a block diagram of a configuration of a UE in accordance with a second exemplary embodiment;

FIG. 5 shows a flow of a TAU process in accordance with a second exemplary embodiment;

FIG. 6 shows a flow of a TAU process in accordance with a second exemplary embodiment;

FIG. 7 shows a location update request message in accordance with a second exemplary embodiment;

FIG. 8 shows a flow of a handover process in accordance with a second exemplary embodiment;

FIG. 9 is a block diagram of a configuration of a mobile communication system in accordance with a second exemplary embodiment;

FIG. 10 shows the contents set in a context response message in accordance with a third exemplary embodiment;

FIG. 11 shows the contents set for the indication set in the indication flags in accordance with the third exemplary embodiment;

FIG. 12 shows content established for MME / SGSN EPS EPS UEs of PDN connections established in a context response message in accordance with a third exemplary embodiment;

FIG. 13 shows the contents of an ARD in accordance with a fourth exemplary embodiment;

FIG. 14 shows a flow of a handover process in accordance with a fifth exemplary embodiment; and

FIG. 15 shows a flow of an authentication process performed between an AAA server, an HSS, and an MME in accordance with a fifth exemplary embodiment.

DESCRIPTION OF EMBODIMENTS

[0022] First Exemplary Embodiment

Exemplary embodiments in accordance with the present invention are explained below with reference to the drawings. An example configuration of a mobile communication system in accordance with a first exemplary embodiment of the present invention is explained with reference to FIG. 1. The mobile communication system shown in FIG. 1 includes a mobile communication terminal 10, PGW 11, HSS 12, and a mobility management device 100. The mobile communication system shown in FIG. 1, designed by using mainly node devices specified in 3GPP.

[0023] The mobile communication terminal 10 may be a mobile phone terminal, a smartphone terminal, a tablet terminal, and the like. Alternatively, the mobile communication terminal 10 may be a 2M (inter-machine) terminal, an MTC (machine-type communication) terminal, and the like. Alternatively, the mobile communication terminal 10 may be a computer device that operates when the processor executes a program stored in memory. It is assumed that the mobile communication terminal 10 is a terminal capable of communication in a 3GPP communication zone and in a non-3GPP communication zone.

[0024] PGW 11, HSS 12, and mobility management device 100 are nodal devices whose functions and operations are specified in 3GPP. Each of PGW 11, HSS 12, and mobility management device 100 may be a computer device that operates when a processor executes a program stored in memory.

[0025] The PGW 11 establishes a PDN connection used to communicate with the mobile communication terminal 10. A PDN connection is established between the mobile communication terminal 10 and the PGW 11 through an eNB (developed Node B) (not shown) or RNC (radio network controller) (not shown). Each of the eNB and RNC is a device whose functions and operations are specified in 3GPP. The eNB is a base station that supports LTE (Long Term Evolution) as a radio method. An RNC is a nodal device that supports a radio method called ʺ2G (second generation mobile phone) ʺ or ʺ3G (third generation mobile phone) ʺ. In addition, a PGW ID, which is an identifier uniquely identified in a communication system, is assigned to PGW 11. The communication system may be, for example, EPS (Advanced Packet System).

[0026] The HSS 12 stores the PGW ID of that PGW that established the PDN connection used to communicate with the mobile communication terminal 10. The mobility management device 100 performs mobility management for the mobile terminal 10 (or supports tracking the movement of the mobile terminal 10). Mobility management may, for example, include managing location information that changes when the mobile communication terminal 10 moves. In addition, the mobility management device 100 may be an MME or SGSN (Serving GPRS Support Node).

[0027] Note that the mobile communication terminal 10 transmits a TAU request message to the mobility management device 100 at regular intervals. More specifically, the mobile communication terminal 10 transmits a TAU request message to the mobility management device 100 through the eNB.

[0028] The tracking area contains at least one cell. The tracking area is, for example, information controlled by the mobility management device 100. In other words, the mobility management device 100 monitors the tracking area as the location information of the mobile communication terminal 10. Further, when the mobility management device 100 calls the mobile communication terminal 10, the mobility management device 100 makes a paging call for all mobile communication terminals located in the tracking area associated with the mobile communication terminal 10.

[0029] When the mobility management device 100 receives a TAU request message transmitted from the mobile communication terminal 10, the mobility management device 100 transmits the ULR message in which the PGW ID is set to the HSS 12 regardless of the storage state of the PGW ID in the HSS 12.

[0030] The mobility management device 100 transmits an ULR message to the HSS 12 to update the location information of the mobile communication terminal 10 monitored in the HSS 12. The HSS 12 typically captures the PGW ID of said PGW 11, which established the PDN connection used to communicate with the mobile terminal communication 10, during the process of joining the mobile communication terminal 10. Additionally, the HSS 12 stores the PGW ID of said PGW 11 when associated with the mobile communication terminal 10. However, when the HSS 12 restarts due to a failure or the like, the HSS 12 deletes all the PGW IDs that the HSS 12 stores. Therefore, there is a case where the HSS 12 does not store the PGW ID for the PGW 11 associated with the mobile communication terminal 10.

[0031] The mobility management device 100 transmits a ULR message in which a PGW ID for PGW 11 is set, regardless of whether the HSS 12 stores a PGW ID for PGW 11 associated with the mobile communication terminal 10. When the HSS 12 receives the ULR message, while the HSS 12 already stores the PGW ID of the PGW 11, and the stored PGW ID is the same as the received PGW ID, the HSS 12 need not update the PGW ID of the PGW 11 associated with terminal 10 mobile communications. On the other hand, when the PGW ID stored in the HSS 12 is different from the PGW ID set in the ULR message, the HSS 12 overwrites the stored PGW ID with the PGW ID set in the ULR message and stores the new PGW ID.

[0032] When the HSS 12 receives the ULR message, while the HSS 12 does not store the PGW ID of said PGW 11, the HSS 12 stores the PGW ID set in the ULR message when associated with the mobile communication terminal 10.

[0033] The above expression “regardless of whether the HSS 12 stores the PGW ID for the PGW 11” can also be expressed as “regardless of whether, for example, the LICH mobility management device 100 records or not records for the mobile communication terminal 10 that transmitted the message TAU request as ʺ not confirmed ’. That is, the mobility management device 100 transmits the ULR message in which the PGW ID is set to the HSS 12, regardless of whether, for example, the LICH mobility management device 100 controls or not records for the mobile terminal 10 that has transmitted the TAU request message as not confirmed.

[0034] As explained above, the mobility management device 100 transmits the ULR message in which the PGW ID is set to the HSS 12, whether or not the HSS 12 stores the PGW ID for the PGW 11 that established the PDN connection used to communicate with a mobile communication terminal 10 that has transmitted a TAU request message. In other words, the mobility management device 100 transmits the ULR message in which the PGW ID is set to the HSS 12, regardless of whether, for example, the LICH mobility management device 100 controls or not records for the mobile terminal 10 that transmitted the TAU request message as not confirmed.

[0035] In this way, even when the mobile terminal 10 has made a move that affects or requires an MME change after restarting the HSS 12, the HSS 12 can capture the PGW ID of said PGW 11 that established the PDN connection used to communicate with the mobile terminal 10 . Therefore, even if the MME to which the mobile communication terminal 10 transmitted the TAU request message before restarting the HSS 12 is different from the MME to which the mobile communication terminal 10 transmitted the TAU request message after restarting the HSS 12, the handover process of the mobile communication terminal 10 can be performed properly. Further, even if the mobile communication terminal 10 has moved from the 3GPP communication zone to the non-3GPP communication zone, the handover process of the mobile communication terminal 10 can be performed properly.

[0036] That is, the HSS 12 can update the PGW ID of said PGW 11, which established the PDN connection used to communicate with the mobile communication terminal 10, while the mobile communication terminal 10 transmits a TAU request message. Therefore, even if the mobile communication terminal 10 has made a move that affects or requires an MME change in the 3GPP communication zone after restarting the HSS 12, and then further moved to the non-3GPP communication zone, the HSS 12 can transmit the PGW ID relating to the mobile communication terminal 10 , to an AAA server. Therefore, it is possible to identify the PGW ID of said PGW 11, which is used as an anchor point, even in the non-3GPP communication area, and thereby properly perform the handover process for the mobile communication terminal 10. Note that the HSS 12 shown in FIG. 1 may also be referred to as a “subscriber information management device”.

[0037] Second Exemplary Embodiment

Next, an example configuration of a mobile communication system in accordance with a second exemplary embodiment of the present invention is explained with reference to FIG. 2. The mobile communication system shown in FIG. 2 includes PGW 11, HSS 12, MME 13, MME 14, UE 20, AAA server 31, IP access device 32, eNB 40, eNB 41, SGW 50, SGW 60 and PCRF 70. PGW 11 and HSS 12 are similar to those in FIG. 1, and therefore, their detailed description is omitted. Additionally, in FIG. 2, explanations are provided when using the MME 13 as the mobility management device 100.

[0038] The UE 20 corresponds to the mobile communication terminal 10 in FIG. 1. UE 20 is used as a generic term for mobile communication terminals in 3GPP. The AAA server 31 is a device that authenticates the UE 20 in a non-3GPP communication area. Additionally, the AAA server 31, which interacts with the HSS 12, receives the PGW ID of the PGW 11 that established the PDN connection used to communicate with the UE 20 from the HSS 12.

[0039] The IP access device 32 is a device that communicates with the UE 20 in a non-3GPP communication area. For example, the IP access device 32 may be an access point in a wireless LAN or a device that performs mobile communication with the UE 20 using a communication method other than the communication method specified in 3GPP. Note that the IP access device 32 may be a non-3GPP trusted access network, ePDG (advanced packet data gateway) or TWAN (WLAN trusted access network) described in Non-Patent Document 3, chapter 16. Alternatively, the IP access device 32 can to be WT (termination of wireless LAN).

[0040] Further, the IP access device 32 captures the PGW ID associated with the UE 20 from the AAA server 31. The IP access device 32 accesses the PGW 11 using the captured PGW ID. In this way, the IP access device 32 can relay transmissions between the PGW 11, which is used as the anchor point, and the UE 20.

[0041] Each of the eNBs 40 and 41 communicates with the UE 20 using LTE as a radio communication method. Additionally, the SGW 50 relays the transmissions between the eNB 40 and the PGW 11, and the SGW 60 relays the transmissions between the eNB 41 and the PGW 11. The PCRF 70 is a host device that controls the QoS policy and the like related to the UE 20.

[0042] FIG. 2 shows that the UE 20 moves from a tracking area managed by MME 13 to a tracking area managed by MME 14, and then moves to a non-3GPP communication area. The solid lines in FIG. 2 indicate control information or C-plane information that is transmitted or received. The broken lines in FIG. 2 indicate user data or U-plane information that is transmitted or received. Additionally, arrows between UE 20 in FIG. 2 indicate that the UE 20 is moving.

[0043] Additionally, in the second exemplary embodiment, the processes are mainly explained in the case where, after restarting the HSS 12, the UE 20 moves from the tracking area managed by the MME 13 to the tracking area managed by the MME 14, and then moves to non-3GPP communication area.

[0044] Next, an example configuration of MME 13 in accordance with a second exemplary embodiment of the present invention is explained with reference to FIG. 3. The configuration of the MME 14 is similar to that of the MME 13, and therefore, its detailed explanation is omitted here. MME 13 includes a communication unit 15 (it may also be referred to as a “transmit and receive unit”) and a control unit 16. The communication unit 15 and the control unit 16 may be software or a module that is driven by the processor executing a program stored in memory. Alternatively, the communication unit 15 and the control unit 16 may be hardware, such as a circuit or chip.

[0045] The communication unit 15 communicates with the eNB 40, HSS 12, and MME 14. Additionally, the communication unit 15 communicates with the UE 20 through the eNB 40. The control unit 16 generates messages to be transmitted to the eNB 40, MME 14, and HSS 12 by communication unit 15. Additionally, the control unit 16 analyzes the messages received from the eNB 40, MME 14 and HSS 12.

[0046] For example, the control unit 16 transmits a notification request message in which the PGW ID of that PGW 11 that established the PDN connection used to communicate with the UE 20 is established to the HSS 12 through the communication unit 15 in the process of connecting the UE 20. Additionally, when the control unit 16 receives the TAU request message transmitted from the UE 20 via the eNB 40, the control unit 16 transmits the ULR message in which the PGW ID of that PGW 11 that established the PDN connection used to communicate with the UE 20 is established to the HSS 12 by communication unit 15.

[0047] Further, when the control unit 16 receives the reset notification from the HSS 12, the control unit 16 controls, i.e. records the LICH relating to UE 20 as “not confirmed”.

[0048] Next, an example configuration of the UE 20 in accordance with the second exemplary embodiment of the present invention is explained with reference to FIG. 4. UE 20 includes a 3GPP communication unit 21 and a non-3GPP communication unit 22. The 3GPP communication unit 21 and the non-3GPP communication unit 22 may be software or a module 22 that is driven by the processor executing a program stored in memory. Alternatively, the 3GPP communication unit 21 and the non-3GPP communication unit 22 may be hardware, such as a circuit or chip.

[0049] The 3GPP communication unit 21 communicates with the eNB 40. For example, the 3GPP communication unit 21 communicates with the eNB 40 using LTE as a radio communication method. When the UE 20 transitions from the power-off state to the power-on state, the 3GPP communication unit 21 transmits a join request message to the eNB 40. Additionally, the 3GPP communication unit 21 transmits a TAU request message for transmitting the location information of the UE 20 to the eNB 40 at regular intervals. Alternatively, the 3GPP communication unit 21 transmits a TAU request message to the eNB 40 when the UE 20 has made a move that affects or requires an MME change.

[0050] The non-3GPP communication unit 22 performs radio communication with the IP access device 32. For example, a non-3GPP communication unit 22 may communicate in a wireless LAN with an IP access device 32 or communicate with an IP access device 32 using other communication methods.

[0051] Further, the flows of the TAU process and the handover process in the 3GPP communication zone in accordance with the second exemplary embodiment of the present invention are explained with reference to FIG. 5 and 6. FIG. 5 and 6 are based on FIG. 5.3.3.1-1 on 3GPP TS 23.401 V13.1.0 (2014-12). Additionally, FIG. 5 and 6 are based on the premise that the HSS 12 restarts (S1) and then transmits a reset notification to MME 13 and 14 (S2 and S3). First, the UE 20 decides to start the TAU process (S11). For example, when the UE 20 has made a move that affects or requires an MME change, or detects periodic timing when the TAU process needs to be started, the UE 20 starts the TAU process. In FIG. 5, the TAU process flow is illustrated in the case where the UE 20 has performed a move that affects the change in the MME.

[0052] Then, the UE 20 transmits a TAU request message to the MME 14 through the eNB 41 (S12 and S13). MME 14 is an MME (new MME) that controls the UE 20 after moving the UE 20. Additionally, the MME (old MME) that controlled the UE 20 before moving the UE 20 is an MME 13.

[0053] Then, the MME 14 transmits a context request message to the MME 13 that controlled the UE 20 before moving the UE 20 to request the MME 13 to transmit subscriber information and the like related to the UE 20 (S14). Then, the MME 13 transmits a context response message in which subscriber information and the like, including a PGW ID related to the UE 20, to the MME 14 (S15) are set. Then, the authentication process for the UE 20 between the UE 20 and the MME 14 and then between the MME 14 and the HSS 12 (S16) is performed.

[0054] Then, the MME 14 transmits a context confirmation message to the MME 13 to instruct the MME 13 to change, as the UE 20 has moved, the gateway device that services the UE 20 from the SGW (serving node) 50 to the SGW 60 (S17).

[0055] Then, the MME 14 transmits a session creation request message to the SGW 60 to instruct the SGW 60 to generate a bearer channel between the SGW 60 and the PGW 11 (S18). Then, the SGW 60 transmits a carrier channel modification request message to the PGW 11 to request generation of a communication carrier channel (S19). Then, in response to the carrier channel modification request message, the PGW 11 transmits the carrier channel modification response message to the SGW 60 (S20). Then, in response to the session creation request message transmitted in step S18, the SGW 60 transmits the session creation response message to the MME 14 (S21). In this way, the UE 20 establishes a PDN connection between the UE 20 and the PGW 11 through the SGW 60.

[0056] Then, the MME 14 transmits a location update request message in which the active AVP APN is established, including the PGW ID of that PGW 11 that established the PDN connection used to communicate with the UE 20 to the HSS 12 (S22). FIG. 7 shows a location update request message in which an active AVP APN is installed. FIG. 7 is based on 3GPP TS 29.272 V13.2.0 (2015-06), Table 5.2.1.1.1 / 1. MME 14 establishes an active AVP APN including the PGW ID of that PGW 11 that established the PDN connection used to communicate with the UE 20 in the location update request message, regardless of whether it is being controlled, i.e. whether or not LICH is recorded for UE 20 as “not confirmed”. In other words, the MME 14 sets the active AVP APN including the PGW ID in the location update request message, regardless of whether the PGW ID in the HSS 12 should be reset due to a restart of the HSS 12 or due to a reset process. Additionally, the MME 14 captures PGW ID information from the MME 13 through a context response message. Therefore, the MME 14 can connect to the same PGW as the PGW with which the MME 14 was connected before the UE moved using the captured PGW ID and thereby properly perform handover even after restarting the HSS.

[0057] Further, a flow of a handover process from a 3GPP communication zone to a non-3GPP communication zone in accordance with a second exemplary embodiment of the present invention is explained with reference to FIG. 8. FIG. 8 is based on FIG. 8.2.2-1 non-patent document. It is assumed that the UE 20 first performs communication in the 3GPP communication area. It is assumed that at this point, the communication carrier channel is established between the SGW 60 and PGW 11 using PMIPv6 or a GTP tunnel (S31).

[0058] Next, a case is explained in which the UE 20 has moved from a 3GPP communication zone to a non-3GPP communication zone. At this point, the UE 20 discovers an IP access device 32 (S32). When the UE 20 detects the IP access device 32, an authentication process between the UE 20 and the IP access device 32 is performed (S33). Additionally, authentication for the UE 20 is also performed on the network (S34). In the authentication process in step S34, the AAA server 31 issues a request to the HSS 12, captures the PGW ID of that PGW 11 that established the PDN connection used to communicate with the UE 20, and transmits this PGW ID to the AAA proxy 71. Note, that the AAA proxy 71 is used as the proxy server of the AAA server 31.

[0059] Further, in the authentication process in step S34, the AAA proxy 71 transmits the PGW ID received from the AAA server 31 to the IP access device 32.

[0060] Then, the UE 20 performs an L3 connection start process between the UE 20 and the IP access device 32 (S35). In this way, for example, the UE 20 transmits APN information that was used in communicating in the 3GPP communication area with the IP access device 32.

[0061] Then, the procedure for establishing a gateway control session is performed between the IP access device 32 and vPCRF (function of the policy and charging rules) 72 and then between vPCRF 72 and hPCRF 73 (S36). PCRFs are host devices that manage QoS policies and the like related to UE 20. vPCRF 72 performs, when the UE 20 roams, policy management related to the UE 20 in the network to which the UE 20 moved during the roaming process. hPCRF 73 performs policy management related to the UE 20 in the home network of the UE 20.

[0062] In step S36, hPCRF 73 transmits QoS policy information and the like related to UE 20 to vPCRF 72. Additionally, vPCRF 72 transmits (ie, forwards) QoS policy information and the like related to UE 20 , to the IP device 32 access.

[0063] Then, the IP access device 32 transmits a proxy binding update message to the PGW 11 using the PGW ID for the PGW 11 received in step S34 (S37). By receiving the proxy binding update message, the PGW 11 associates the PDN connection used to communicate with the UE 20 in the 3GPP communication zone with the carrier channel or the communication connection in the non-3GPP communication zone and performs the handover process of the UE 20.

[0064] As previously explained, by using a mobile communication system in accordance with a second exemplary embodiment of the present invention, the HSS 12 can capture the PGW ID for PGW 11, which established the PDN connection used to communicate with the UE 20, each time when the UE 20 performs the TAU process. In other words, the MME 14 transmits the PGW ID for the PGW 11 that established the PDN connection used to communicate with the UE 20 to the HSS 12 each time the UE 20 performs the TAU process, regardless of whether it was controlled, i.e. whether or not LICH was recorded as “not confirmed”.

[0065] In this way, even if the UE 20 has made a move that affects or requires an MME change after restarting the HSS 12, the HSS 12 can receive the PGW ID for the PGW 11 that established the PDN connection used to communicate with the UE 20 from the MME 14 which performs mobility management for the UE 20 after moving the UE 20 (S22). Therefore, the AAA server 31 can capture the PGW ID related to the UE 20 from the HSS 12 even after the HSS 12 restarts. Therefore, the UE 20 can access the same PGW after the move as the PGW accessed by the UE 20 before the move , and therefore, can properly perform handover from the 3GPP communication zone to the non-3GPP communication zone using that PGW as the anchor point. As a result, the UE can continue to receive service from an external network through the same PGW, even from the area where the UE has moved.

[0066] Note that the second exemplary embodiment has been explained using mainly the MME as the mobility management device 100. However, as shown in FIG. 9, SGSN 110 and SGSN 111 may be used in place of the MME. In this case, MME 13 and 14 in FIG. 2 are replaced by SGSN 110 and 111, respectively. Additionally, eNB 40 and 41 in FIG. 2 are replaced by RNC 130 and 131, respectively. Additionally, HSS 12 in FIG. 2 is replaced by HLR 120. In this case, the UE 20 performs the RAU (roaming zone update) process instead of the TAU process and transmits the RAU request message to the SGSN 111 through the RNC 131.

[0067] Third Exemplary Embodiment

Next, a flow of a TAU process in accordance with a third exemplary embodiment is explained. The flow of the TAU process in accordance with the third exemplary embodiment is similar to that explained in the second exemplary embodiment with reference to FIG. 5 and 6, with the exception of differences in the content specified in the messages. Therefore, the third exemplary embodiment is explained with particular emphasis on messages in which content other than that in messages according to the second exemplary embodiment shown in FIG. 5 and 6.

[0068] Additionally, in the third exemplary embodiment, it is proposed that the HSS 12 restarts and sends a reset notification to the MME 13. Additionally, the MME 13 receives the reset notification, the MME 13 controls or records the LICH for the UE 20 as “not acknowledged”.

[0069] Further, the UE 20 moves from the place where the UE 20 is controlled by the MME 13 to the place where the UE 20 is controlled by the MME 14. Even in a situation like this, the UE 20 performs the TAU process in step S11 and subsequent steps in FIG. . 5.

[0070] Steps S11-S14 are similar to those in the second exemplary embodiment. When the MME 13 determines or recognizes that the TAU process for the UE 20 is performed in step S14, the MME 13 transmits a context response message stating that the LICH for the UE 20 is set or recorded as “not confirmed” to the MME 14 in step S15 .

[0071] The content set in the context response message is explained below with reference to FIG. 10. FIG. 10 is based on 3GPP TS29.274 V13.2.0 (2015-06), table 7.3.6-1. FIG. 10 shows that “MME / SGSN UE EPS PDN Connections”, which indicate that there is data established for each PDN connection, are set in the context response message. Additionally, FIG. 10 shows that the information element (IE) of the ʺMME / SGSN UE EPS PDN Connectionsʺ type is a ʺPDN Connectionʺ. Additionally, FIG. 10 shows that the LICH is added to the Indication Flags of the context response message. Additionally, FIG. 10 shows that an IE of type FlIndication Flagsʺ is a ʺIndicationʺ.

[0072] The content of the indication set in the indication flags of the context response message is explained below with reference to FIG. 11. FIG. 11 is based on 3GPP TS29.274 V13.2.0 (2015-06), FIG. 8.12-1. FIG. 11 shows that the LICH flag is set in bit 5 of octet 9. For example, when ʺ1ʺ is set in bit 5 of octet 9, this indicates that the active APN should be set in the location update request message when the MME 14 transmits the update request message locations to HSS 12. That is, when ʺ1ʺ is set in bit 5 of octet 9, this indicates that LICH corresponds to ʺ not confirmed ’.

[0073] The content set in the MME / SGSN UE EPS PDN Connections of the context response message is explained below with reference to FIG. 12. FIG. 12 is based on 3GPP TS29.274 V13.2.0 (2015-06), table 7.3.6-2. FIG. 12 shows that a context identifier indicating identification information of a PDN connection has been added. A context identifier is information used to identify a PDN connection, and is used when an active AVP APN is transmitted, as explained below. Therefore, the MME 13 sets the context identifier together with a flag indicating that the LICH for the UE 20 corresponds to “not confirmed” in the context response message. Additionally, the MME 13 transmits a context response message including the PGW ID of said PGW 11 to the MME 14. In this example, the PGW ID information is transferred from the MME 13 to the MME 14 using the information element (IE) of the MME / SGSN UE EPS PDN Connections However, PGW ID information may be carried using a special IE.

[0074] With reference to FIG. 5 and 6, steps S16-S21 are similar to those in the second exemplary embodiment. In step S22, since the LICH for the UE 20 corresponds to “Not Confirmed”, the MME 14 transmits a ULR message in which an active AVP APN is established, including a PGW ID for PGW 11 that established the PDN connection used to communicate with the UE 20 to the HSS 12. For example, in step S15, when the MME 14 receives a context response message in which ʺ 1ʺ is set in bit 5 of octet 9, respectively, of the indication indicating area, the MME 14 sets the context identifier set in the context response in step S15 to the active AVP APN. As a result, in step S22, the MME 14 transmits a ULR message in which the active AVP APN is established, including the PGW ID for PGW 11, which established the PDN connection used to communicate with the UE 20, to the HSS 12.

[0075] As explained above, the MME 14, which is responsible for managing the UE 20 after moving it, can recognize the LICH control state for the UE 20 through a context response message transmitted from the MME 13 that controlled the UE 20 before moving it. That is, even if the MME that controls the UE 20 changes from the MME 13 to the MME 14 due to the movement of the UE 20, the MME 14 can take over the LICH control state. Therefore, the HSS 12 can capture the PGW ID for PGW 11, which established the PDN connection used to communicate with the UE 20, by receiving the ULR message from the MME 14.

[0076] As a result, even if the UE 20 made a move that affects or requires an MME change and then moved to a non-3GPP communication area, the AAA server 31 can capture the PGW ID for PGW 11, which established the PDN connection used for communication with the UE 20, from the restarted HSS 12. Therefore, the UE 20 may properly perform handover from the 3GPP communication zone to the non-3GPP communication zone.

[0077] Fourth Exemplary Embodiment

Next, a flow of a TAU process in accordance with a fourth exemplary embodiment is explained. The flow of the TAU process in accordance with the fourth exemplary embodiment is similar to that which was explained in the second exemplary embodiment with reference to FIG. 5 and 6, with the exception of differences in the content specified in the messages. Therefore, the fourth exemplary embodiment is explained with particular emphasis on messages in which content other than messages in the second exemplary embodiment shown in FIG. 5 and 6.

[0078] Further, in the fourth exemplary embodiment, it is assumed that the HSS 12 is restarted and sends a reset notification to the MME 13. Additionally, the MME 13 receives the reset notification, the MME 13 controls or records the LICH for the UE 20 as “not acknowledged”.

[0079] Further, the UE 20 moves from the place where the UE 20 is controlled by the MME 13 to the place where the UE 20 is controlled by the MME 14. Even in a situation like this, the UE 20 performs the TAU process in step S11 and subsequent steps in FIG. . 5.

[0080] Additionally, in 3GPP TS 29.272 V13.2.0 (2015-06), Table 7.7.31 / 1, it is specified that access restriction data (ARD), which indicate an access network in which the use of UE 20 is restricted, is stored in the HSS 12. As shown in FIG. 13, in the ARD, the zones where the ARDs are set and the restrictions associated with these zones are specified. For example, when ʺ1ʺ is set in bit 5 corresponding to the zone indicating the ARD, this indicates that the UE 20 is not allowed to be transmitted to the non-3GPP communication area for service. Additionally, when ʺ0ʺ is set in each of the bits corresponding to the zones indicating ARD, this indicates that the use of the access network associated with this bit is not limited.

[0081] Additionally, the HSS 12 transmits the ARD information to the MME 13. For example, in the batch process TAU UE 20, the HSS 12 sets the ARD information in the location update response message, which is a response message to the location update request message, and sends a response message location updates to MME 13.

[0082] Note that when the MME 13 determines or recognizes that the TAU process for the UE 20 is performed in step S14 in FIG. 5, MME 13 checks whether ʺ0ʺ is set in bit 5 corresponding to the zone indicating ARD for UE 20. The fact that ʺ0ʺ is set in bit 5 corresponding to the zone indicating ARD indicates that UE 20 is allowed to be transferred to non-service 3GPP communication zone.

[0083] When the MME 13 determines that the TAU process for the UE 20 is running, and the MME 13 confirms that ʺ 0ʺ is set to bit 5 corresponding to the area indicating the ARD for the UE 20, the MME 13 transmits instruction information to the MME 14. More specifically, the MME 13 establishes information instructing to transmit the ULR message in which the active APN is established, including the PGW ID for PGW 11, which established the PDN connection used to communicate with the UE 20, to the HSS 12 in the context response message, and transmits this context response message to the MME 14. Bit 5 corresponding to the zone indicating the ARD is a flag, state-binding HTN3AA (handover to non-3GPP-access is not allowed). Note that the information of this state can be determined using data other than ARD. Then, the MME 13 may set this information in a context response message and notify the MME 14 of this information.

[0084] After capturing information instructing to transmit the ULR message including the active AVP APN to the HSS 12 in step S15, the MME 14 transmits the ULR message in which the active APN including the PGW ID is set to the HSS 12 in step S22 .

[0085] Further, when ʺ 0 ʺ is set in bit 5, respectively, in a zone indicating the ARD of the UE 20, and the LICH is set or recorded as “not acknowledged”, the MME 13 may set information instructing to transmit the ULR message in which the active APN including the PGW ID is set. PGW 11, which established the PDN connection used to communicate with UE 20, to HSS 12 in a context response message. Then, the MME 13 may transmit this context response message to the MME 14.

[0086] As explained above, the MME 13 may transmit instruction information related to the contents of the ULR message to the MME 14, which controls the UE 20 after moving it, using the restriction information specified in the ARD. That is, the MME 13 may instruct the MME 14 to set the PGW ID of the PGW 11 for which the UE 20 has established a communication bearer in the ULR message.

[0087] Additionally, in the fourth exemplary embodiment, the MME 14 sets the active APN in the ULR message only if the UE 20 is allowed to be handed over to a non-3GPP communication area. Therefore, when the processes of the fourth exemplary embodiment are executed, the amount of information of the ULR message can be reduced compared with that in the first or second exemplary embodiments in which the active APN is set in the ULR message all the time.

[0088] Note that in the third and fourth exemplary embodiments, SGSN 110 and 111 can also be used instead of MME 13 and 14. RNC 130 and 131 can be used instead of eNB 40 and 41. Additionally, HLR 120 can be used instead of HSS 12 In this case, the UE 20 performs the RAU process instead of the TAU process and transmits the RAU request message to the SGSN 111 through the RNC 131.

[0089] Fifth Exemplary Embodiment

Further, the flow of the handover process from the 3GPP communication zone to the non-3GPP communication zone in accordance with the fifth exemplary embodiment is explained with reference to FIG. 14 and 15. FIG. 14 is based on FIG. 8.2.2-1 of Non-Patent Document 3. It is assumed that the UE 20 first performs communication in the 3GPP communication zone. It is assumed that at this point, the communication carrier channel is established between the SGW 60 and PGW 11 using PMIPv6 or a GTP tunnel (S31).

[0090] The following explains the case where the UE 20 has moved from a 3GPP communication zone to a non-3GPP communication zone. At this point, the UE 20 detects the IP access device 32 (S32). When the UE 20 detects the IP access device 32, an authentication process between the UE 20 and the IP access device 32 is performed (S33). Additionally, authentication for the UE 20 is also performed within the network (S34). In the authentication process in step S34, the HSS 12 / AAA server 31 must transmit the PGW ID PGW 11 that established the PDN connection used to communicate with the UE 20 to the AAA proxy 71. However, it is likely that the PGW ID PGW 11 that established the PDN connection used by the HSS 12 to communicate with the UE 20 can be removed from the HSS 12 due to a restart of the HSS 12. In this case, the HSS 12 issues a request to the MME 14 to which the UE 20 has moved, and thus captures PGW ID for PGW 11, which established the PDN connection used to communicate with UE 20. Then, the HSS 12 transmits the PGW ID for PGW 11 to the AAA proxy 71. AAA Proxy 71 is used as the proxy server of the AAA server 31.

[0091] An authentication process that is performed between the AAA server 31, the HSS 12, and the MME 14 when the PGW ID for the PGW 11 that established the PDN connection used by the HSS 12 to communicate with the UE 20 was deleted from the HSS 12 due to a restart HSS 12 is explained below in detail with reference to FIG. 15. When the restart operation is started in the HSS 12 (S41), the HSS 12 sends a reset message (RESET) to the corresponding MME (S42). After receiving the reset message, the MME 14 creates a list of all subscribers supported (or recorded) in the HSS 12 from which the reset message was sent, sets the created list to the reset response message (RESET ANSWER), and transmits the reset response message to the HSS 12 (S43) . The subscriber list established in this process may contain IMSI (International Mobile Subscriber Identifiers) or may contain other user identifiers. By storing a list of subscribers for each MME, the HSS 12 can manage the relationship between the subscribers and the MME to which the subscribers have moved during and after the reset process. These relationships enable request operations from HSS 12 to MME 14, which will be explained below. However, this relationship can also be used for other operations, such as searching for the location of the subscriber after putting the network into operation and providing services from the MTC server. Here, it is assumed that the UE 20 has moved from a 3GPP communication zone to a non-3GPP communication zone (S44).

[0092] As an authentication request for UE 20, the HSS 12 receives the access request, authentication and authorization message STa from the AAA server 31 (S45). In the access request, authentication and authorization message STa, a parameter corresponding to the IMSI is set as the user identifier. If the HSS 12 does not store the PGW ID corresponding to the user ID, the HSS 12 further transmits a status request message to the MME (S46). This message includes subscriber information corresponding to the IMSI and an information element requesting PGW ID information for PGW 11 that has established the PDN connection used to communicate with UE 20. Additionally, the status request message may be a reset request message (RESET REQUEST ) or other messages. After receiving the status request message, the MME 14 sets the PGW ID information for the PGW 11, which established the PDN connection used to communicate with the UE 20, in the status response message and transmits the status response message to the HSS 12 (S47). Additionally, the status response message may be a RESET ANSWER message or other messages. The HSS 12 transmits a non-3GPP access, authentication, and authorization trust message in which the PGW ID information for the PGW 11 that established the PDN connection used to communicate with the UE 20 is established to the AAA server 31 (S48).

[0093] Here, again with reference to FIG. 14, the explanation of step S34 and subsequent steps continues.

[0094] In the authentication process in step S34, the AAA proxy 71 transmits the PGW ID received from the HSS 12 / AAA server 31 to the IP access device 32.

[0095] Then, the UE 20 performs an L3 start-up connection process between the UE 20 and the IP access device 32 (S35). In this way, for example, the UE 20 transmits APN information that was used in the communication in the 3GPP communication zone to the IP access device 32.

[0096] Then, a procedure for establishing a gateway control session between the IP access device 32 and vPCRF (function of the policy and charging rules) 72 and then between vPCRF 72 and hPCRF 73 (S36) is performed. PCRFs are host devices that manage QoS policies and the like related to UE 20. vPCRF 72 performs, when the UE 20 roams, policy management related to the UE 20 in the network to which the UE 20 moved during the roaming process. hPCRF 73 performs policy management related to the UE 20 in the home network of the UE 20.

[0097] In step S36, hPCRF 73 transmits QoS policy information and the like related to UE 20 to vPCRF 72. Additionally, vPCRF 72 transmits (ie, forwards) QoS policy information and the like related to UE 20 , to the IP device 32 access.

[0098] Then, the IP access device 32 transmits a proxy binding update message to PGW 11 using the PGW ID for PGW 11 received in step S34 (S37). By receiving the proxy binding update message, the PGW 11 associates the PDN connection used to communicate with the UE 20 in the 3GPP communication zone with the carrier channel or the communication connection in the non-3GPP communication zone and performs the handover process of the UE 20.

[0099] As previously explained, by using a mobile communication system in accordance with a second exemplary embodiment of the present invention, the HSS 12 may issue a request to the MME 14 to which the UE 20 has moved using an authentication process request sent from the AAA server 31 as a trigger. As a result, HSS 12 can capture the PGW ID for PGW 11, which established the PDN connection used to communicate with UE 20.

[0100] In this way, even if the UE 20 has made a move that affects or requires an MME change after restarting the HSS 12, the HSS 12 can receive the PGW ID for PGW 11, which established the PDN connection used to communicate with the UE 20, from the MME 14 that performs mobility management for the UE 20 after moving the UE 20. Therefore, the AAA server 31 can capture the PGW ID related to the UE 20 from the HSS 12 even after restarting the HSS 12. Therefore, the UE 20 can access the same PGW after moving as the PGW, to which the UE 20 accessed before moving, and therefore can properly in this way, perform handover from the 3GPP communication zone to the non-3GPP communication zone using that PGW as the anchor point. As a result, the UE can continue to receive service from an external network through the same PGW, even from the area where the UE has moved.

[0101] Further, in the fifth exemplary embodiment, even if the HSS 12 is restarted, and immediately after the MME receives the reset signal (RESET), the UE 20 has moved from the 3GPP communication zone to the non-3GPP communication zone without communicating with the MME at all The AAA server 31 may capture the PGW ID for PGW 11, which established the PDN connection used to communicate with UE 20. Therefore, preferred results similar to those described above can be achieved.

[0102] Note that the fifth exemplary embodiment has been explained using mainly the MME as the mobility management device 100. However, as shown in FIG. 9, SGSN 110 and SGSN 111 may be used in place of the MME. In this case, MME 13 and 14 in FIG. 2 are replaced by SGSN 110 and 111, respectively. Additionally, eNB 40 and 41 in FIG. 2 are replaced by RNC 130 and 131, respectively. Additionally, HSS 12 in FIG. 2 is replaced by HLR 120. In this case, the UE 20 performs the RAU (roaming zone update) process instead of the TAU process and transmits the RAU request message to the SGSN 111 through the RNC 131.

[0103] Although the present invention is described in hardware configuration in the above exemplary embodiments, the present invention is not limited to hardware configurations. In the present invention, the processes in each of the node devices forming the mobile communication system can also be implemented by causing the CPU (central processing unit) to execute a computer program.

[0104] In the above examples, the program may be stored on non-temporary computer-readable media of various types and therefore provided to computers. Non-temporary computer-readable media include various types of tangible storage media. Examples of non-temporary computer-readable media include a magnetic recording medium (such as a floppy disk, a magnetic tape and a hard disk drive), a magneto-optical recording medium (such as a magneto-optical disk), CD-ROM (read-only memory), CD-R and CD-R / W and semiconductor memory (such as mask ROM, PROM (programmable ROM), EPROM (erasable PROM), flash ROM and RAM (random access memory)). Additionally, the program can be provided to computers using various types of computer-readable transient (transit) media. Examples of transient computer-readable media include an electrical signal, an optical signal, and an electromagnetic wave. Transitional computer-readable media can be used to provide programs to a computer via a wired communication channel, such as an electric wire or optical fiber, or a wireless communication channel.

[0105] Note that the invention is not limited to the above exemplary embodiments, and various changes can be made therein without departing from the spirit and scope of the present invention.

[0106] Although the present invention is explained above with reference to exemplary embodiments, the present invention is not limited to the above exemplary embodiments. Various modifications that may be understood by those skilled in the art can be made in the configuration and details of the present invention within the scope of the invention.

[0107] This application is based on and claims the priority of Japanese Patent Application No. 2015-193034, filed September 30, 2015, the disclosure of which is incorporated herein by reference.

[0108] All or part of the exemplary embodiments disclosed above may be described, but not limited to, by the following additional notes.

[0109] (Additional Note 1)

A mobile communication system comprising:

PGW configured to establish a PDN connection used to communicate with a mobile communication terminal;

An HSS configured to store a PGW ID, wherein the PGW ID is a PGW identifier; and

a mobility management device configured to perform mobility management of a mobile communication terminal, wherein

when the mobility management device receives a tracking zone update message transmitted from the mobile communication terminal, the mobility management device transmits a location update request message including a PGW ID set therein to the HSS regardless of the storage state of the PGW ID in the HSS.

(Supplementary Note 2)

The mobile communication system described in Supplementary Note 1, wherein

when the mobility management device that performs mobility management of the mobile communication terminal is changed from the first mobility management device to the second mobility management device due to movement of the mobile communication terminal,

the first mobility management device transmits a context response message including registration information for the mobile communication terminal installed therein to the second mobility management device, and

the second mobility management device transmits a location update request message including a PGW ID set therein to the HSS when information indicating that the HSS is restarted is set in the registration information.

(Supplementary Note 3)

The mobile communication system described in Supplementary Note 1, wherein

when the mobility management device that performs mobility management of the mobile communication terminal is changed from the first mobility management device to the second mobility management device due to movement of the mobile communication terminal,

the first mobility management device transmits a context response message including instruction information set therein to the second mobility management device based on at least one of the access restriction data and information indicating that the HSS is restarted, the instruction information instructing the second device the mobility management to transmit a location update request message including a PGW ID set therein to the HSS.

(Supplementary Note 4)

A mobile communication system described in Supplementary Note 2 or 3, wherein

the first mobility management device transmits a context response message including a context identifier set therein to the second mobility management device, the context identifier being an identifier of a PDN connection, and

the second mobility management device transmits a location update request message in which an active AVP APN, including a context identifier, and a PGW ID, is set to the HSS.

(Supplementary Note 5)

A mobility management device comprising a communication unit configured to, after receiving a tracking area update message transmitted from a mobile communication terminal, transmit a location update request message including a PGW ID set therein to the HSS regardless of the storage state of the PGW ID in An HSS storing a PGW ID, wherein the PGW ID is the PGW ID of that PGW that established the PDN connection used to communicate with the mobile communication terminal.

(Supplementary Note 6)

The mobility management device described in Supplementary Note 5, wherein

when the mobility management device that performs mobility management of the mobile communication terminal is changed from the first mobility management device to its own device due to movement of the mobile communication terminal,

the communication unit receives a context response message including registration information for a mobile communication terminal set therein, transmitted from the first mobility management device, and transmits a location update request message including a PGW ID set therein to the HSS when the information indicating that the HSS is restarted is set in the login information.

(Supplementary Note 7)

The mobility management device described in Supplementary Note 6, wherein

the communication unit receives a context response message including a context identifier set therein from the first mobility management device, the context identifier being an identifier of a PDN connection, and transmits a location update request message in which an active AVP APN including an identifier is set context, and PGW ID, to HSS.

(Supplementary Note 8)

The mobility management device described in Supplementary Note 5, wherein

when the mobility management device that performs mobility management of the mobile communication terminal is changed from its own device to the second mobility management device due to movement of the mobile communication terminal,

the communication unit transmits a context response message in which registration information for the mobile communication terminal, including information that the HSS is restarted, is set to the second mobility management device.

(Supplementary Note 9)

The mobility management device described in Supplementary Note 5, wherein

when the mobility management device that performs mobility management of the mobile communication terminal is changed from its own device to the second mobility management device due to movement of the mobile communication terminal,

the communication unit transmits a context response message including instruction information set therein to the second mobility management device based on at least one of the access restriction data and information indicating that the HSS is restarted, the instruction information instructing the second mobility management device transmit a location update request message including a PGW ID set therein to the HSS.

(Supplementary Note 10)

The mobility management device described in supplementary note 8 or 9, wherein the communication unit transmits a context response message including a context identifier set therein to the second mobility management device, wherein the context identifier is an identifier of a PDN connection.

(Supplementary Note 11)

A communication method comprising, after receiving a tracking area update message transmitted from a mobile communication terminal, transmitting a location update request message including a PGW ID set therein to the HSS regardless of the storage state of the PGW ID in the HSS storing the PGW ID, wherein PGW ID is the PGW ID of the PGW that established the PDN connection used to communicate with the mobile communication terminal.

(Supplementary Note 12)

The communication method described in supplementary note 11, further comprising

when the mobility management device that performs mobility management of the mobile communication terminal is changed from the first mobility management device to its own device due to movement of the mobile communication terminal,

after receiving the tracking zone update message transmitted from the mobile communication terminal, receiving a context response message including registration information for the mobile communication terminal set therein transmitted from the first mobility management device, and

transmitting a location update request message including a PGW ID set therein to the HSS when information indicating that the HSS is restarted is set in the registration information.

(Supplementary Note 13)

The communication method described in supplementary note 11, further comprising

when the mobility management device that performs mobility management of the mobile communication terminal is changed from its own device to the second mobility management device due to movement of the mobile communication terminal,

transmitting a context response message in which registration information for the mobile communication terminal is set, including information that the HSS is restarted, to the second mobility management device in the process of updating the tracking area for the mobile communication terminal.

(Supplementary Note 14)

A program for causing a computer to execute, after receiving a tracking zone update message transmitted from a mobile communication terminal, transmitting a location update request message including a PGW ID set therein to the HSS regardless of the storage state of the PGW ID in the HSS storing the PGW ID, wherein the PGW ID is the PGW ID of that PGW that established the PDN connection used to communicate with the mobile communication terminal.

LIST OF REFERENCE POSITIONS

[0110]

10 mobile terminal

11 PGW

12 HSS

13 MME

14 MME

15 control unit

16 control unit

20 UE

21 3GPP communication unit

22 non-3GPP communication unit

31 AAA server

32 IP access device

40 eNB

41 eNB

50 SGW

60 SGW

70 PCRF

71 AAA proxies

72 vPCRF

73 hPCRF

100 mobility management device

110 SGSN

111 SGSN

120 HLR

130 RNC

131 RNC.

Claims (41)

1. A communication system comprising: a packet data network (PDN) gateway (P-GW) configured to establish a PDN connection between the P-GW and user equipment; a subscriber information management device configured to store a P-GW identifier (P-GW ID), which is an identifier for a P-GW; a mobility management entity (MME) configured to perform mobility management for user equipment that supports handover to a network other than a 3rd Generation Partnership Project (3GPP) network, and wherein in the case where the MME is replaced and the subscriber information management device is reset, the new MME transmits a message with the P-GW ID set to the subscriber information management device in the tracking area update procedure (TAU) or routing area update procedure (RAU). 2. The communication system according to claim 1, in which in the case where the MME is replaced after the subscriber information management device is reset, the new MME transmits a message with the set P-GW ID to the subscriber information management device in the TAU procedure or in the RAU procedure. 3. The communication system according to claim 1 or 2, in which the new MME is further configured to receive the TAU request message or the RAU request message from the user equipment and transmit the message with the set P-GW ID to the subscriber information management device in the TAU procedure or the RAU procedure based on the TAU request message or the RAU request message. 4. A mobility management entity (MME) for performing mobility management of user equipment that supports handover to a network other than the 3rd Generation Partnership Project (3GPP) network on a network, the MME comprising: a transmitter configured to, in case the MME is replaced, and a subscriber information management device configured to store a P-GW identifier (P-GW ID), which is an identifier for a packet data network (PDN) gateway (P-GW) configured to establish a PDN connection between the P-GW and the user equipment is reset, send a message with the established P-GW ID to the subscriber information management device in the tracking zone update procedure (TAU) or routing zone update procedure (RAU). 5. The object of mobility management (MME) according to claim 4, in which the transmitter is configured to, in the event that the MME is changed after the subscriber information management device is reset, transmit a message with the set P-GW ID to the subscriber information management device in the TAU procedure or RAU procedure. 6. A mobility management entity (MME) according to claim 4 or 5, further comprising: a receiver configured to receive a TAU request message or a RAU request message from the user equipment, and in which the transmitter is further configured to transmit a message with the established P-GW ID to the subscriber information management device in the TAU procedure or the RAU procedure based on the TAU request message or the RAU request message. 7. A method for managing mobility, comprising: in the case where a mobility management entity (MME) performing mobility management of user equipment that supports handover to a network other than the 3rd Generation Partnership Project (3GPP) network is changed in the network, and the subscriber information management device configured to store the P-GW ID (P-GW ID), which is the identifier for the packet data network (PDN) gateway (P-GW) configured to establish a PDN connection between the P-GW and the user equipment, is reset by I receive messages with a set P-GW ID to the subscriber information management device in the procedure for updating the tracking zone (TAU) or the procedure for updating the routing zone (RAU). 8. A method for managing mobility according to claim 7, comprising in the case where the MME changes after the subscriber information management device is reset, transmitting the message with the set P-GW ID to the subscriber information management device in the TAU procedure or RAU procedure. 9. A method for managing mobility according to claim 7 or 8, further comprising: receiving a TAU request message or a RAU request message from a user equipment; and sending a message with a set P-GW ID to the subscriber information management device in the TAU procedure or the RAU procedure based on the TAU request message or the RAU request message. 10. A computer-readable medium storing instructions that, when executed by a computer, cause the computer to implement a method comprising: in the case where a mobility management entity (MME) performing mobility management of user equipment that supports handover to a network other than the 3rd Generation Partnership Project (3GPP) network on the network is replaced, and the subscriber information management device configured is to store the P-GW identifier (P-GW ID), which is the identifier for the packet data network (PDN) gateway (P-GW) configured to establish a PDN connection between the P-GW and the user equipment, is reset, p soap has message with the P-GW ID to the subscriber information management device in the procedure of the tracking area update (TAU) procedure, or a Routing Area Update (RAU). 11. Machine-readable media according to claim 10, wherein in the case where the MME changes after the subscriber information management device is reset, a message with a set P-GW ID is transmitted to the subscriber information management device in the TAU procedure or RAU procedure. 12. User equipment supporting handover to a network other than the 3rd Generation Partnership Project (3GPP) network in a network comprising: memory storing instructions; and at least one processor configured to process instructions to: establish a packet data network (PDN) connection between the PDN gateway (P-GW) and user equipment; transmit a tracking zone update request message (TAU) or a routing zone update request message (RAU) to the network, and moreover, in the case where a mobility management entity (MME) performing mobility management for user equipment is changed, and a subscriber information management device configured to store a P-GW identifier (P-GW ID), which is an identifier for P-GW, is reset at least one processor is further configured to process instructions to cause a new MME to transmit a message with a set P-GW ID to a subscriber information management device by transmitting a message TAU request message or a RAU request to the new MME. 13. User equipment according to claim 12, in which in the case where the MME changes after the subscriber information management device is reset, at least one processor is configured to process instructions to cause the new MME to send a message with the PGW ID set to the subscriber information management device by transmitting a TAU request message or a request message RAU to the new MME. 14. A communication method for user equipment supporting a handover to a network other than the 3rd Generation Partnership Project (3GPP) network on a network, the method comprising: establishing a packet data network (PDN) connection between a PDN gateway (P-GW) and user equipment; transmitting a tracking zone update request message (TAU) or a routing zone update request message (RAU) to the network; and the motivation, in the case where a mobility management entity (MME) performing mobility management for user equipment is changed, and a subscriber information management device configured to store a P-GW identifier (P-GW ID), which is an identifier for P-GW , is reset, of the new MME to transmit the message with the PGW ID set to the subscriber information management device by transmitting the TAU request message or the RAU request message to the new MME. 15. The communication method according to p. 14, in which prompting the new MME to transmit the message with the PGW ID set to the subscriber information management device by transmitting the TAU request message or the RAU request message to the new MME is performed when the MME is replaced after the subscriber information management device is reset.

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