JP2012044556A - Mobile communication method and policy control node - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mobile communication method and policy control node, capable of offering position information, such as cell ID, from an EPC network to an IMS infrastructure.SOLUTION: In a mobile communication method, a bearer is established through a mobile management node MME, position information of a mobile terminal UE is acquired from a radio base station eNodeB or the mobile management node MME and transmitted to a policy control node PCRF. The position information is transmitted from the policy control node PCRF to a call control node P-CSCF.

Description

  The present invention relates to a mobile communication method and policy control node for providing information such as a cell ID from an EPC network to an IMS base.

IMS (IP Multimedia Subsystem) is predetermined as a 3GPP (3 ^rd Generation Partnership Project) international standard for the purpose of providing IP-based multimedia communications services. IMS is a concept of a core network that communicates using IP that does not depend on an access network. Each access network is called an IP-CAN, and a plurality of IP-CANs can be accommodated seamlessly. Since IMS does not depend on an access network, it is possible to provide a common network service (for example, answering machine, call waiting, transfer service, etc.) in different access networks. A mobile communication system using this IMS is defined in Non-Patent Document 1.

  FIG. 1 is a diagram showing a network architecture when an access network is an LTE (Long Term Evolution) network in IMS. In the 3GPP international standard, an IP mobile transmission network is defined as an EPC (Evolved Packet Core) network, and a service control network is defined as an IMS. In the LTE access system, the eNodeB that is the base station is accommodated by an MME (Mobility Management Entity) and an S-GW (Serving-Gateway). The MME has an interface with a mobile terminal UE (User Equipment) located in the radio zone of the LTE access system, and performs mobility management of the mobile terminal UE, authentication of the mobile terminal, and setting control of an IP transmission path with the mobile terminal. The S-GW performs IP packet transmission control based on an MME command.

  Also, in the EPC network, P-GW (Packet Data Network) -Gateway (P-GW) and Policy and Charging Rules Function (PCRF) are set. The P-GW has a connection point with a PDN such as the Internet or IMS, and receives all IP packets from the PDN to the mobile terminal UE. The PCRF determines an IP packet transmission policy such as QoS (Quality of Service) and charging method for performing transmission quality control in the P-GW and S-GW.

  The IMS mainly includes a session control function (CSCF) and an application service control function (AS). The IMS also includes a user information storage function (HSS).

  CSCF (Call Session Control Function) is a function that performs session control, which is the core of control of a service control network. Session control is performed by selecting and setting AS according to the setting and release of a communication session between mobile terminals and service conditions. A SIP (Session Initiation Protocol) signal as a protocol is transferred. The CSCF is divided into three functional elements: P-CSCF (Proxy-CSCF), S-CSCF (Serving-CSCF), and I-CSCF (Interogating-CSCF).

  AS (Application Server) performs common basic control or general control of each application service in cooperation with a mobile terminal. The HSS (Home Subscriber Server) is a database that handles user information of mobile terminals that access the service control network. In FIG. 1, a broken line indicates C-Plane (user data), and a solid line indicates U-Plane (control signal).

  On the other hand, in Non-Patent Document 1, position information such as Cell ID is defined. Cell ID is an identifier of an area obtained by further subdividing the coverage area of one radio base station, and is defined as Enhanced Cell Global Identity (E-CGI) in LTE. The position information includes an area code and a tracking area ID. This area code is held in the MME or eNodeB, and the tracking area ID is held in the MME.

3GPP TS 23.003

  FIG. 2 is a sequence diagram for explaining attach control from the LTE access system. First, the mobile terminal UE makes a connection request to the MME via the eNodeB. At this time, the eNodeB sends the Cell ID to the MME. Thereafter, the mobile terminal UE performs security procedures such as authentication and concealment. Thereafter, the MME sends a location registration request message to the HSS. Moreover, MME performs a session production | generation request | requirement with respect to S-GW and P-GW. At this time, MME sends Cell ID to S-GW. Thereafter, when a session is established between the P-GW and the PCRF, the Cell ID is sent to the PCRF via the P-GW. Thus, as shown in FIG. 1, the Cell ID is held by the MME, S-GW, and PCRF by the attach control.

  In the IMS specification in the current 3GPP international standard, IMS can acquire the Cell ID from the mobile terminal, but cannot acquire it from the access network. However, it is desirable to make it possible to acquire the cell ID of the mobile terminal from the access network from the viewpoint of security such as tampering. In addition, as a typical use of a trusted Cell ID, a reliable element at the time of charging, a location specifying element at the time of communication interception, an element for specifying an appropriate connection destination when making an emergency call, and other IMS There are elements when providing services. From this point of view, it is desirable to be able to acquire the cell ID of the mobile terminal from the access network.

  The present invention has been made in view of this point, and an object of the present invention is to provide a mobile communication method and policy control node that provide location information such as Cell ID from an EPC network to an IMS base.

  The mobile communication method of the present invention includes a step of establishing a bearer via a mobility management node, a step of acquiring location information of the mobile terminal from the radio base station or the mobility management node, and transmitting the location information to a policy control node; And the step of transmitting the location information from the policy control node to a call control node.

  The policy control node of the present invention is a policy control node that holds location information of a mobile terminal, and is acquired from the radio base station or the mobility management node after a bearer is established via the mobility management node. Position information is held, and the position information is transmitted to the call control node.

  According to the present invention, the latest location information that is acquired when a bearer is established, and the latest location information where the user is located when a call is made or received is notified on the IMS base. Therefore, IMS can handle highly reliable position information.

It is a figure which shows a network architecture in case an access network is an LTE network in IMS. It is a sequence diagram for demonstrating the attach control from a LTE access system. It is a figure for demonstrating the mobile communication method of this invention. It is a figure which shows the PMIP sequence (Cell ID acquisition) which concerns on the mobile communication method of this invention. It is a figure which shows the GTP sequence (Cell ID acquisition) which concerns on the mobile communication method of this invention. It is a figure which shows the PMIP sequence (Cell ID acquisition) which requests | requires acquisition from P-CSCF based on the mobile communication method of this invention. It is a figure which shows the GTP sequence (Cell ID acquisition) which requests | requires acquisition from P-CSCF based on the mobile communication method of this invention. It is a figure which shows the PMIP sequence (area code acquisition) which concerns on the mobile communication method of this invention. It is a figure which shows the PMIP sequence (area code acquisition) which requests | requires acquisition from P-CSCF based on the mobile communication method of this invention. It is a figure which shows the PMIP sequence (Tracking Area ID acquisition) which concerns on the mobile communication method of this invention. It is a figure which shows the PMIP sequence (Tracking Area ID acquisition) which requests | requires acquisition from P-CSCF based on the mobile communication method of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a diagram showing a network architecture when an access network is an LTE network in IMS according to an embodiment of the present invention. As described above, in the 3GPP international standard, the IP mobile transmission network is defined as an EPC network, and the service control network is defined as an IMS. In the LTE access system, the eNodeB that is the base station is accommodated by the MME and the S-GW.

  The mobility management node MME has an interface with a mobile terminal UE located in the radio zone of the LTE access system, and performs mobility management of the mobile terminal UE, authentication of the mobile terminal, and control of setting of an IP transmission path with the mobile terminal. The MME performs mobility management and authentication of the mobile terminal UE in cooperation with the HSS. Moreover, MME sets the transmission path | route of the IP packet which the mobile terminal UE transmits / receives with respect to S-GW and eNodeB.

  The gateway device S-GW performs transmission control of IP packets based on a command from the MME. When transmitting the IP packet, the S-GW performs transmission quality control of the IP packet according to the QoS information notified from the PCRF.

  In the EPC network, P-GW and PCRF are set. The P-GW has a connection point with a PDN such as the Internet or IMS, and receives all IP packets from the PDN to the mobile terminal UE. The P-GW transmits the received IP packet to the mobile terminal UE to the S-GW or the like. Further, when the gateway device P-GW transmits the IP packet, the gateway device P-GW controls the transmission quality of the IP packet according to the QoS information notified from the PCRF.

  The policy control node PCRF determines an IP packet transmission policy such as QoS (Quality of Service) and charging method for performing transmission quality control in the P-GW and S-GW. The IP packet transmission policy is determined based on service application information requested from the mobile terminal UE, user service contract information, and the like notified from the IMS.

  The IMS mainly includes a session control function (CSCF) and an application service control function (AS). The IMS also includes a user information storage function (HSS).

  The call control node CSCF is a function that performs session control, which is the core of control of the service control network, and is a session control protocol that sets and releases a communication session between mobile terminals and selects an AS according to service conditions. Transfer SIP signal. The call control node CSCF is divided into three functional elements: P-CSCF, S-CSCF, and I-CSCF. The call control node CSCF also includes an E-CSCF.

  The P-CSCF is deployed at a connection point with the IP mobile transmission network, is connected to the P-GW of the IP mobile transmission network, and relays SIP signals between the S-CSCF and the I-CSCF and the mobile terminal UE. The P-CSCF confirms the validity of the SIP signal sent from the mobile terminal UE, and adds information (such as charging information) necessary for session control to the S-CSCF. On the other hand, information that should not be transmitted to the mobile terminal UE (such as a caller ID when receiving an incoming call with no number notification) is deleted. Further, the P-CSCF notifies the PCRF of application type information necessary for performing QoS control by IMS.

  The S-CSCF performs session control and authentication using user information obtained from the HSS. Further, when the S-CSCF receives a session activation signal from the mobile terminal UE, the S-CSCF selects an AS corresponding to the service according to the information of the initial filter criteria and relays the SIP signal.

  The I-CSCF conceals the S-CSCF from other networks and relays SIP signals between the other networks and the S-CSCF as a gateway to the IMS. The I-CSCF selects the S-CSCF according to the user information of the HSS during registration with the IMS and session control.

  The E-CSCF (Emergency-CSCF) performs the acquisition of the location information of the mobile terminal and the selection of an appropriate emergency reporting station according to the location information.

  The application server AS performs common basic control or general control of each application service in cooperation with the mobile terminal. Specifically, the S-CSCF relays the SIP signal with the mobile terminal UE to the AS, and the AS performs service control. Further, the AS acquires user information related to the application service from the HSS, and performs authentication and authorization for the application.

  The home subscriber server HSS is a database that handles user information of mobile terminals that access the service control network. Specifically, it holds a private user identifier, a public user identifier, an address of an S-CSCF that performs session control, contract service information, security information, information on initial filter criteria, and the like. The HSS reads and writes information from the S-CSCF, I-CSCF, and AS.

  In the present invention, when location information such as a cell ID of a mobile terminal is transmitted from the LTE network to the IMS, a signal used when the mobility management node MME establishes a bearer for the radio base station eNodeB is used. The position information is acquired and notified to the IMS side. Thereby, in IMS, the newest position information can be acquired.

  In the mobile communication method of the present invention, as shown in FIG. 3, QoS information is instructed from the IMS-based call control node to the policy control node of the EPC network (AAR signal, AAA signal of Diameter Base Protocol) (step ( 1)). Next, a radio bearer between the mobile terminal UE and the radio base station eNodeB is established between the EPC network and the mobile terminal UE and the radio base station eNodeB (steps (2) and (3)). Thereafter, a resource reservation completion notification is sent from the policy control node of the EPC network to the IMS-based call control node (RAR signal, RAA signal of Diameter Base Protocol) (step (4)). In this method, the location information (mobile terminal cell ID, area code, tracking area ID) is notified in bearer establishment response step (3) and resource reservation completion notification step (4).

  For example, the in-zone Cell ID held by the policy control node (PCRF) of the EPC network is the Cell ID at the time of registration, and it is conceivable that it is not necessarily the Cell ID in which the user is located when making a call. According to the above mobile communication method, since it is the in-zone Cell ID acquired when the radio bearer is established, it is the latest Cell ID in which the user is located when making / receiving calls. As a result, the latest location information can be acquired on the IMS base, and highly reliable location information can be handled by IMS.

  That is, the mobile communication method of the present invention establishes a radio bearer between a mobile terminal and a radio base station via a mobility management node, acquires location information of the mobile terminal from the radio base station, and performs the mobility management. The information is transmitted to a policy control node via a node, and the location information is transmitted from the policy control node to a call control node.

  In this case, it is preferable that the position information transmitted by the RAA signal of the Diameter Base Protocol is transmitted to the call control node by the RAR signal of the Diameter Base Protocol. Further, it is preferable to transmit a Diameter Base Protocol AAA signal to the call control node in response to the Diameter Base Protocol AAR signal transmitted from the call control node. Furthermore, it is preferable that the location information acquisition request signal transmitted together with the AAR signal from the call control node is transmitted to the gateway device as a Diameter Base Protocol RAR signal. In the mobile communication method of the present invention, the location information is preferably a cell ID, area code, and tracking area ID of the mobile terminal. The area code is an information element set in the radio base station, and indicates an installation location of the radio base station (for example, Chiyoda-ku, Tokyo). The Tracking Area ID is information stored in the mobility management node MME in units of mobility management areas in the EPC network.

The mobile communication method of the present invention includes the following sequence.
(1) PMIP (Proxy Mobile Internet Protocol) sequence (Cell ID acquisition) (see FIG. 4)
(2) GTP (GPRS (General Packet Radio Service) Tunneling Protocol) sequence (Cell ID acquisition) (see FIG. 5)
(3) PMIP sequence to request acquisition from P-CSCF (acquire cell ID) (see FIG. 6)
(4) GTP sequence to request acquisition from P-CSCF (acquire cell ID) (see FIG. 7)
(5) PMIP sequence (area code acquisition) (see FIG. 8)
(6) PMIP sequence for acquisition request from P-CSCF (area code acquisition) (see FIG. 9)
(7) PMIP sequence (Tracking Area ID acquisition) (see FIG. 10)
(8) PMIP sequence requesting acquisition from P-CSCF (Tracking Area ID acquisition) (see FIG. 11)
Hereinafter, these sequences will be described.

(1) PMIP sequence (Cell ID acquisition)
In this sequence, as shown in FIG. 4, first, session establishment at the IMS layer is performed. Next, the call control node P-CSCF instructs QoS reservation to the LTE network. That is, the call control node P-CSCF cooperates with the policy control node PCRF to provide the capability (such as usable codecs) of the mobile terminal UE on the transmission side and the reception side and the resource status of the radio access network (in this case, the LTE network). QoS is set according to Specifically, the call control node P-CSCF transmits a Diameter Base Protocol AAR (AA-Request) signal to the policy control node PCRF, and the service information is authenticated and stored in the policy control node PCRF. . Next, the policy control node PCRF transmits an AAA signal (AA-Answer) of the Diameter Base Protocol to the call control node P-CSCF.

  Note that FIG. 4 shows a sequence when a bearer setup request is received from the call control node P-CSCF, but the present invention can be similarly applied to a bearer setup request from a mobile terminal. it can. In FIG. 4, the sequence described below is a sequence that is common to both the bearer setup request from the call control node P-CSCF and the bearer setup request from the mobile terminal.

  The policy control node PCRF determines PCC (Policy and Charging Control) / QoS rules for RTP (Real-time Transport Protocol) / RTCP (RTP Control Protocol). Then, the policy control node PCRF transmits a Diameter Base Protocol RAR (Re-Auth-Request) signal to the gateway device S-GW. In the gateway device S-GW, the QoS rule is installed.

  Next, a radio bearer is established between the mobile terminal UE and the radio base station eNodeB via the mobility management node MME. First, a generated bearer request signal (GTPv2_Create Bearer Request) is transmitted from the gateway device S-GW to the mobility management node MME. The mobility management node MME transmits an E-RAB (EPS-Radio Access Bearer) setup request signal (S1-AP_E-RAB Setup Request) to the radio base station eNodeB. The radio base station eNodeB transmits a radio resource control connection reconfiguration signal (RRC_RRC Connection Reconfiguration) to the mobile terminal UE.

  Next, the mobile terminal UE transmits a radio resource control connection reconfiguration completion signal (RRC_RRC Connection Reconfiguration Complete) to the radio base station eNodeB. Then, the radio base station eNodeB transmits a response signal (S1-AP_E-RAB Setup Response) to the E-RAB setup request signal to the mobility management node MME. Also, the mobile terminal UE transmits an uplink information signal (RRC UL Information Transfer) for radio resource control to the radio base station eNodeB. Then, the radio base station eNodeB transmits a control signal (S1-AP_Uplink NAS (Non-Access Stratum) Transport) for mobility management and session management between the UE and the MME to the mobility management node MME. The radio base station eNodeB transmits, together with this control signal, the Cell-ID of the cell where the mobile terminal UE (user) is located to the mobility management node MME. In addition, this information (Cell-ID of the cell which exists) may be set to S1-AP_E-RAB Setup Response.

  Next, the mobility management node MME transmits a generation bearer response signal (GTPv2_Create Bearer Response) and a Cell ID to the gateway device S-GW. The gateway device S-GW transmits the Diameter Base Protocol RAA signal and Cell ID to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol RAR signal to the gateway device P-GW. The gateway device P-GW installs the PCC rule. The gateway device P-GW transmits an RAA (Re-Auth-Answer) signal of the Diameter Base Protocol to the call control node P-CSCF. The policy control node PCRF transmits the RAR signal and Cell ID of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. In this way, the location information (Cell ID) of the mobile terminal UE is acquired from the radio base station eNodeB, transmitted to the policy control node PCRF via the mobility management node MME, and the location information (Cell ID) from the policy control node PCRF. ) To the call control node P-CSCF.

(2) GTP sequence (Acquire Cell ID)
In this sequence, as shown in FIG. 5, first, session establishment at the IMS layer is performed. Next, the call control node P-CSCF instructs QoS reservation to the LTE network. That is, the call control node P-CSCF cooperates with the policy control node PCRF to provide the capability (such as usable codecs) of the mobile terminal UE on the transmission side and the reception side and the resource status of the radio access network (in this case, the LTE network). QoS is set according to Specifically, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol (authentication, approval, and accounting protocol by peer-to-peer communication) to the policy control node PCRF. Authenticate the service information and store the service information. Next, the policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF.

  Note that FIG. 5 shows a sequence when a bearer setup request is received from the call control node P-CSCF, but the present invention can be similarly applied to a bearer setup request from a mobile terminal. it can. In FIG. 5, the sequence described below is a sequence common to both the bearer setup request from the call control node P-CSCF and the bearer setup request from the mobile terminal.

  The policy control node PCRF determines PCC / QoS rules for RTP / RTCP. And policy control node PCRF transmits the RAR signal of Diameter Base Protocol to gateway apparatus P-GW. The gateway device P-GW installs the QoS rule.

  Next, a radio bearer is established between the mobile terminal UE and the radio base station eNodeB via the mobility management node MME. First, a generated bearer request signal (GTPv2_Create Bearer Request) is transmitted from the gateway device P-GW to the gateway device S-GW, and the gateway device S-GW transmits a generated bearer request signal (GTPv2_Create Bearer Request) to the mobility management node MME. . The mobility management node MME transmits an E-RAB setup request signal (S1-AP_E-RAB Setup Request) to the radio base station eNodeB. The radio base station eNodeB transmits a radio resource control connection reconfiguration signal (RRC_RRC Connection Reconfiguration) to the mobile terminal UE.

  Next, the mobile terminal UE transmits a radio resource control connection reconfiguration completion signal (RRC_RRC Connection Reconfiguration Complete) to the radio base station eNodeB. Then, the radio base station eNodeB transmits a response signal (S1-AP_E-RAB Setup Response) to the E-RAB setup request signal to the mobility management node MME. Also, the mobile terminal UE transmits an uplink information signal (RRC UL Information Transfer) for radio resource control to the radio base station eNodeB. Then, the radio base station eNodeB transmits a mobility management and session management control signal (S1-AP_Uplink NAS Transport) between the UE and the MME to the mobility management node MME. The radio base station eNodeB transmits, together with this control signal, the Cell-ID of the cell where the mobile terminal UE (user) is located to the mobility management node MME. In addition, this information (Cell-ID of the cell which exists) may be set to S1-AP_E-RAB Setup Response.

  Next, the mobility management node MME transmits the generated bearer response signal (GTPv2_Create Bearer Response) and the Cell ID to the gateway device S-GW, and the gateway device S-GW transmits the generated bearer response signal (GTPv2_Create Bearer Response) to the gateway device P-. Send to GW. The gateway device P-GW transmits the Diameter Base Protocol RAA signal and Cell ID to the policy control node PCRF. The policy control node PCRF transmits the RAR signal and Cell ID of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. In this way, the location information (Cell ID) of the mobile terminal UE is acquired from the radio base station eNodeB, transmitted to the policy control node PCRF via the mobility management node MME, and the location information (Cell ID) from the policy control node PCRF. ) To the call control node P-CSCF.

(3) PMIP sequence to request acquisition from P-CSCF (Cell ID acquisition)
This sequence shows a case where the call control node P-CSCF acquires the location information of the mobile terminal UE before setting the voice bearer in the case of an emergency call. As shown in FIG. 6, first, when an emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node P-CSCF, it is determined in the call control node P-CSCF whether it is an emergency call. .

  Next, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol to the policy control node PCRF. At this time, the call control node P-CSCF transmits a cell ID acquisition request signal to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF. Also, the policy control node PCRF transmits a Diameter Base Protocol RAR signal and a Cell ID acquisition request signal to the gateway device S-GW.

  Next, a bearer is established via the mobility management node MME. First, a change bearer request signal (GTPv2_Modify Bearer Request) and a cell ID acquisition request signal are transmitted from the gateway device S-GW to the mobility management node MME. The mobility management node MME transmits a location report request signal (S1-AP_LOCATION REPORTING CONTROL) to the radio base station eNodeB. The radio base station eNodeB transmits a location report request signal (S1-AP_LOCATION REPORT) to the mobility management node MME. The radio base station eNodeB transmits, together with this control signal, the Cell-ID of the cell where the mobile terminal UE (user) is located to the mobility management node MME.

  Next, the mobility management node MME transmits a change bearer response signal (GTPv2_Modify Bearer Response) and a Cell ID to the gateway device S-GW. The gateway device S-GW transmits the Diameter Base Protocol RAA signal and Cell ID to the policy control node PCRF. The policy control node PCRF transmits the RAR signal and Cell ID of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. In this way, the location information (Cell ID) of the mobile terminal UE is acquired from the radio base station eNodeB, transmitted to the policy control node PCRF via the mobility management node MME, and the location information (Cell ID) from the policy control node PCRF. ) To the call control node P-CSCF.

  FIG. 6 includes a procedure for performing location reporting between the mobility management node MME and the radio base station eNodeB, and shows a case where location information (Cell ID) is acquired from the radio base station in the procedure. However, the present invention is not limited to this, the location reporting procedure is not performed, and the location information (Cell ID) held by the mobility management node MME is transmitted from the mobility management node MME via the policy control node PCRF. It may be transmitted to the call control node P-CSCF.

(4) GTP sequence to request acquisition from P-CSCF (acquire cell ID)
This sequence shows a case where the call control node P-CSCF acquires the location information of the mobile terminal UE before setting the voice bearer in the case of an emergency call. As shown in FIG. 7, first, when an emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node P-CSCF, it is determined whether or not the call is an emergency call in the call control node P-CSCF. .

  Next, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol to the policy control node PCRF. At this time, the call control node P-CSCF transmits a cell ID acquisition request signal to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF. Further, the policy control node PCRF transmits the RAR signal of the Diameter Base Protocol and the request signal for obtaining the Cell ID to the gateway device P-GW.

  Next, a bearer is established via the mobility management node MME. First, the gateway device P-GW transmits a change bearer request signal (GTPv2_Modify Bearer Request) and a cell ID acquisition request signal to the gateway device S-GW, and the gateway device S-GW transmits the change bearer request signal (GTPv2_Modify Bearer Request). And a cell ID acquisition request signal is transmitted to the mobility management node MME. The mobility management node MME transmits a location report request signal (S1-AP_LOCATION REPORTING CONTROL) to the radio base station eNodeB. The radio base station eNodeB transmits a location report request signal (S1-AP_LOCATION REPORT) to the mobility management node MME. The radio base station eNodeB transmits, together with this control signal, the Cell-ID of the cell where the mobile terminal UE (user) is located to the mobility management node MME.

  Next, the mobility management node MME transmits the change bearer response signal (GTPv2_Modify Bearer Response) and the Cell ID to the gateway device S-GW, and the gateway device S-GW transmits the change bearer response signal (GTPv2_Modify Bearer Response) and the Cell ID. Transmit to the gateway device P-GW. The gateway device P-GW transmits the Diameter Base Protocol RAA signal and Cell ID to the policy control node PCRF. The policy control node PCRF transmits the RAR signal and Cell ID of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. In this way, the location information (Cell ID) of the mobile terminal UE is acquired from the radio base station eNodeB, transmitted to the policy control node PCRF via the mobility management node MME, and the location information (Cell ID) from the policy control node PCRF. ) To the call control node P-CSCF.

  FIG. 7 includes a procedure in which location reporting is performed between the mobility management node MME and the radio base station eNodeB, and location information (Cell ID) is acquired from the radio base station in the procedure. However, the present invention is not limited to this, the location reporting procedure is not performed, and the location information (Cell ID) held by the mobility management node MME is transmitted from the mobility management node MME via the policy control node PCRF. It may be transmitted to the call control node P-CSCF.

  According to the mobile communication methods of (3) and (4) above, the location information can be notified to the IMS base quickly without going through the QoS setting procedure. It can be handled quickly.

  In the mobile communication methods (3) and (4) above, the emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node E-CSCF, and the call control node E-CSCF determines the emergency call. The call control node P-CSCF may directly send the AAR signal of the Diameter Base Protocol and the request signal for obtaining the Cell ID to the policy control node PCRF, and the emergency call number (SIP_INVITE) is sent from the mobile terminal UE to the call control node. The call control node E-CSCF transmits an emergency call to the E-CSCF, and the call control node E-CSCF sends a Diameter Base Protocol AAR signal and a Cell ID acquisition request signal to the call control node P-CSCF. Via the policy control node PCRF.

(5) PMIP sequence (area code acquisition)
In this sequence, as shown in FIG. 8, first, session establishment at the IMS layer is performed. Next, the call control node P-CSCF instructs QoS reservation to the LTE network. That is, the call control node P-CSCF cooperates with the policy control node PCRF to provide the capability (such as usable codecs) of the mobile terminal UE on the transmission side and the reception side and the resource status of the radio access network (in this case, the LTE network). QoS is set according to Specifically, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol to the policy control node PCRF, and the service information is authenticated and stored in the policy control node PCRF. Next, the policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF.

  Note that FIG. 8 shows a sequence when a bearer setup request is received from the call control node P-CSCF, but the present invention can be similarly applied to a bearer setup request from the mobile terminal. it can. In FIG. 8, the sequence described below is a sequence that is common to both the bearer setup request from the call control node P-CSCF and the bearer setup request from the mobile terminal.

  The policy control node PCRF determines PCC / QoS rules for RTP / RTCP. And policy control node PCRF transmits the RAR signal of Diameter Base Protocol to gateway apparatus S-GW. In the gateway device S-GW, the QoS rule is installed.

  Next, a radio bearer is established between the mobile terminal UE and the radio base station eNodeB via the mobility management node MME. First, a generated bearer request signal (GTPv2_Create Bearer Request) is transmitted from the gateway device S-GW to the mobility management node MME. The mobility management node MME transmits an E-RAB setup request signal (S1-AP_E-RAB Setup Request) to the radio base station eNodeB. The radio base station eNodeB transmits a radio resource control connection reconfiguration signal (RRC_RRC Connection Reconfiguration) to the mobile terminal UE.

  Next, the mobile terminal UE transmits a radio resource control connection reconfiguration completion signal (RRC_RRC Connection Reconfiguration Complete) to the radio base station eNodeB. Then, the radio base station eNodeB transmits a response signal (S1-AP_E-RAB Setup Response) to the E-RAB setup request signal to the mobility management node MME. The radio base station eNodeB transmits an area code together with this control signal to the mobility management node MME (if the radio base station eNodeB holds the area code, the area code is transmitted to the mobility management node MME when the bearer is set up. Set to notify).

  Also, the mobile terminal UE transmits an uplink information signal (RRC UL Information Transfer) for radio resource control to the radio base station eNodeB. Then, the radio base station eNodeB transmits a mobility management and session management control signal (S1-AP_Uplink NAS Transport) between the UE and the MME to the mobility management node MME. The radio base station eNodeB may transmit an area code to the mobility management node MME together with this control signal instead of the response signal (S1-AP_E-RAB Setup Response).

  Next, the mobility management node MME transmits a generation bearer response signal (GTPv2_Create Bearer Response) and an area code to the gateway device S-GW. The gateway device S-GW transmits the RAA signal of the Diameter Base Protocol and the area code to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol RAR signal to the gateway device P-GW. The gateway device P-GW installs the PCC rule. The gateway device P-GW transmits an RAA (Re-Auth-Answer) signal of the Diameter Base Protocol to the policy control node PCRF. The policy control node PCRF transmits the RAR signal and area code of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. In this way, the location information (area code) of the mobile terminal UE is obtained from the radio base station eNodeB, transmitted to the policy control node PCRF via the mobility management node MME, and the location information (area code) from the policy control node PCRF. ) To the call control node P-CSCF.

  Although FIG. 8 shows a PMIP sequence, in the present invention, similarly, in the GTP sequence, the location information (area code) of the mobile terminal UE is acquired from the radio base station eNodeB and passes through the mobility management node MME. It is also possible to transmit to the policy control node PCRF, and to transmit the position information (area code) from the policy control node PCRF to the call control node P-CSCF.

(6) PMIP sequence to request acquisition from the P-CSCF (area code acquisition)
This sequence shows a case where the call control node P-CSCF acquires the location information of the mobile terminal UE before setting the voice bearer in the case of an emergency call. As shown in FIG. 9, first, when an emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node P-CSCF, it is determined whether or not the call is an emergency call in the call control node P-CSCF. .

  Next, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol to the policy control node PCRF. At this time, the call control node P-CSCF transmits an area code acquisition request signal to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF. Further, the policy control node PCRF transmits the RAR signal of the Diameter Base Protocol and the area code acquisition request signal to the gateway device S-GW.

  Next, a bearer is established via the mobility management node MME. First, the gateway device S-GW transmits a change bearer request signal (GTPv2_Modify Bearer Request) and an area code acquisition request signal to the mobility management node MME. The mobility management node MME transmits a location report request signal (S1-AP_LOCATION REPORTING CONTROL) to the radio base station eNodeB. The radio base station eNodeB transmits a location report request signal (S1-AP_LOCATION REPORT) to the mobility management node MME. The radio base station eNodeB transmits an area code together with this control signal to the mobility management node MME. When the radio base station eNodeB holds an area code, it may be set to notify the mobility management node MME, and an “area code acquisition request” is set from the mobility management node MME, and this acquisition request You may take the procedure of the response to.

  Next, the mobility management node MME transmits a change bearer response signal (GTPv2_Modify Bearer Response) and an area code to the gateway device S-GW. The gateway device S-GW transmits the RAA signal of the Diameter Base Protocol and the area code to the policy control node PCRF. The policy control node PCRF transmits the RAR signal and area code of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. In this way, the location information (area code) of the mobile terminal UE is obtained from the radio base station eNodeB, transmitted to the policy control node PCRF via the mobility management node MME, and the location information (area code) from the policy control node PCRF. ) To the call control node P-CSCF.

  FIG. 9 includes a procedure in which location reporting is performed between the mobility management node MME and the radio base station eNodeB, and the location information (area code) is acquired from the radio base station in the procedure. However, the present invention is not limited to this, the location reporting procedure is not performed, and the location information (area code) held by the mobility management node MME is transmitted from the mobility management node MME via the policy control node PCRF. It may be transmitted to the call control node P-CSCF.

  In the mobile communication method of (6) above, the emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node E-CSCF, the emergency call is determined by the call control node E-CSCF, and the call control is performed. The node P-CSCF may directly transmit the Diameter Base Protocol AAR signal and the area code acquisition request signal to the policy control node PCRF, and the emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node E-CSCF. The call control node E-CSCF determines the emergency call, and the call control node E-CSCF controls the AAR signal of the Diameter Base Protocol and the area code acquisition request signal via the call control node P-CSCF. It may be transmitted to the node PCRF.

  The E-UTRAN Global Cell ID is composed of MCC, MNC, and ECI. The ECI is eNodeB ID (20 bits) + Cell ID (8 bits) in the case of a macro base station, and eNodeB in the case of a femto base station. ID (28 bits). E-CGI may change the mapping with the physical area depending on the operation. Therefore, it is necessary to change the “E-CGI-physical area” mapping database in the E-CSCF for selecting the emergency call station in accordance with the change of the E-CGI. If the E-CSCF can acquire the area code, it is not necessary to change the database as described above, and the operation cost can be reduced.

  FIG. 9 shows a PMIP sequence. In the present invention, in the GTP sequence, similarly, the location information (area code) of the mobile terminal UE is acquired from the radio base station eNodeB and passes through the mobility management node MME. It is also possible to transmit to the policy control node PCRF, and to transmit the position information (area code) from the policy control node PCRF to the call control node P-CSCF.

(7) PMIP sequence (Tracking Area ID acquisition)
In this sequence, as shown in FIG. 10, first, session establishment at the IMS layer is performed. Next, the call control node P-CSCF instructs QoS reservation to the LTE network. That is, the call control node P-CSCF cooperates with the policy control node PCRF to provide the capability (such as usable codecs) of the mobile terminal UE on the transmission side and the reception side and the resource status of the radio access network (in this case, the LTE network). QoS is set according to Specifically, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol to the policy control node PCRF, and the service information is authenticated and stored in the policy control node PCRF. Next, the policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF.

  Note that FIG. 10 shows a sequence when a bearer setup request is received from the call control node P-CSCF, but the present invention can be similarly applied to a bearer setup request from the mobile terminal. it can. In FIG. 10, the sequence described below is a sequence that is common to both the bearer setup request from the call control node P-CSCF and the bearer setup request from the mobile terminal.

  The policy control node PCRF determines PCC / QoS rules for RTP / RTCP. And policy control node PCRF transmits the RAR signal of Diameter Base Protocol to gateway apparatus S-GW. In the gateway device S-GW, the QoS rule is installed.

  Next, a radio bearer is established between the mobile terminal UE and the radio base station eNodeB via the mobility management node MME. First, a generated bearer request signal (GTPv2_Create Bearer Request) is transmitted from the gateway device S-GW to the mobility management node MME. The mobility management node MME transmits an E-RAB setup request signal (S1-AP_E-RAB Setup Request) to the radio base station eNodeB. The radio base station eNodeB transmits a radio resource control connection reconfiguration signal (RRC_RRC Connection Reconfiguration) to the mobile terminal UE.

  Next, the mobile terminal UE transmits a radio resource control connection reconfiguration completion signal (RRC_RRC Connection Reconfiguration Complete) to the radio base station eNodeB. Then, the radio base station eNodeB transmits a response signal (S1-AP_E-RAB Setup Response) to the E-RAB setup request signal to the mobility management node MME.

  Also, the mobile terminal UE transmits an uplink information signal (RRC UL Information Transfer) for radio resource control to the radio base station eNodeB. Then, the radio base station eNodeB transmits a mobility management and session management control signal (S1-AP_Uplink NAS Transport) between the UE and the MME to the mobility management node MME.

  Next, the mobility management node MME transmits a generated bearer response signal (GTPv2_Create Bearer Response) and a Tracking Area ID to the gateway device S-GW. The gateway device S-GW transmits the Diameter Base Protocol RAA signal and Tracking Area ID to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol RAR signal to the gateway device P-GW. The gateway device P-GW installs the QoS rule. The gateway device P-GW transmits an RAA (Re-Auth-Answer) signal of the Diameter Base Protocol to the call control node P-CSCF. The policy control node PCRF transmits the RAR signal and Tracking Area ID of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. Thus, the location information (Tracking Area ID) of the mobile terminal UE is acquired from the mobility management node MME and transmitted to the policy control node PCRF, and the location information (Tracking Area ID) is received from the policy control node PCRF. -Send to CSCF.

  FIG. 10 shows a PMIP sequence. In the present invention, similarly, in the GTP sequence, the location information (Tracking Area ID) of the mobile terminal UE is obtained from the mobility management node MME and is sent to the policy control node PCRF. It is also possible to transmit the location information (Tracking Area ID) from the policy control node PCRF to the call control node P-CSCF.

(8) PMIP sequence to request acquisition from P-CSCF (Tracking Area ID acquisition)
This sequence shows a case where the call control node P-CSCF acquires the location information of the mobile terminal UE before setting the voice bearer in the case of an emergency call. As shown in FIG. 11, first, when an emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node P-CSCF, it is determined whether the call is an emergency call in the call control node P-CSCF. .

  Next, the call control node P-CSCF transmits an AAR signal of Diameter Base Protocol to the policy control node PCRF. At this time, the call control node P-CSCF transmits a tracking area ID acquisition request signal to the policy control node PCRF. The policy control node PCRF transmits a Diameter Base Protocol AAA signal to the call control node P-CSCF. Further, the policy control node PCRF transmits a Diameter Base Protocol RAR signal and a tracking area ID acquisition request signal to the gateway device S-GW.

  Next, a bearer is established via the mobility management node MME. First, a change bearer request signal (GTPv2_Modify Bearer Request) and a tracking area ID acquisition request signal are transmitted from the gateway device S-GW to the mobility management node MME. The mobility management node MME transmits a location report request signal (S1-AP_LOCATION REPORTING CONTROL) to the radio base station eNodeB. The radio base station eNodeB transmits a location report request signal (S1-AP_LOCATION REPORT) to the mobility management node MME.

  Next, the mobility management node MME transmits a change bearer response signal (GTPv2_Modify Bearer Response) and a Tracking Area ID to the gateway device S-GW. The gateway device S-GW transmits the Diameter Base Protocol RAA signal and Tracking Area ID to the policy control node PCRF. The policy control node PCRF transmits the RAR signal and area code of the Diameter Base Protocol to the call control node P-CSCF. The call control node P-CSCF transmits a Diameter Base Protocol RAA signal to the policy control node PCRF. Thus, the location information (Tracking Area ID) of the mobile terminal UE is acquired from the mobility management node MME and transmitted to the policy control node PCRF, and the location information (Tracking Area ID) is received from the policy control node PCRF. -Send to CSCF.

  In the mobile communication method of (6) above, the emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node E-CSCF, the emergency call is determined by the call control node E-CSCF, and the call control is performed. The node P-CSCF may directly transmit the AAR signal of the Diameter Base Protocol and the tracking area ID acquisition request signal to the policy control node PCRF, and the emergency call number (SIP_INVITE) is transmitted from the mobile terminal UE to the call control node E-CSCF. The call control node E-CSCF makes an emergency call determination, and the call control node E-CSCF sends a Diameter Base Protocol AAR signal and a tracking area ID acquisition request signal via the call control node P-CSCF. It may be transmitted to the policy control node PCRF.

  FIG. 11 shows a PMIP sequence. In the present invention, similarly, in the GTP sequence, the location information (Tracking Area ID) of the mobile terminal UE is obtained from the mobility management node MME and is sent to the policy control node PCRF. It is also possible to transmit the location information (Tracking Area ID) from the policy control node PCRF to the call control node P-CSCF.

  Although the present invention has been described in detail using the above-described embodiments, it will be apparent to those skilled in the art that the present invention is not limited to the embodiments described herein. For example, in the above embodiment, the signal name in the sequence is an example, and the signal name is not limited to this, and may be another signal name. In addition, the present invention can be implemented as a modification and update mode without departing from the spirit and scope of the present invention defined by the description of the scope of claims. Therefore, the description of the present specification is for illustrative purposes and does not have any limiting meaning to the present invention.

S-CSCF, P-CSCF, I-CSCF, E-CSCF Call control node PCRF Policy control node P-GW, S-GW Gateway device MME Mobility management node AS Application server HSS Home subscriber server eNodeB Radio base station UE Mobile terminal

Claims (12)

  Establishing a bearer via a mobility management node; obtaining location information of the mobile terminal from the radio base station or the mobility management node; and transmitting the location information to a policy control node; and from the policy control node, the location information. Transmitting to the call control node. A mobile communication method comprising:   The mobile communication method according to claim 1, wherein the location information is transmitted to the policy control node by an RAA signal of Diameter Base Protocol, and the location information is transmitted to the call control node by an RAR signal of Diameter Base Protocol.   The call control node transmitting a Diameter Base Protocol AAR signal to a policy control node; and the policy control node transmitting a Diameter Base Protocol AAA signal for the AAR signal to the call control node. The mobile communication method according to claim 1 or 2, further comprising:   The mobile communication method according to claim 3, wherein the call control node transmits an acquisition request signal for the location information together with the AAR signal to the policy control node.   5. The mobile communication method according to claim 4, wherein the policy control node transmits the acquisition request signal to the gateway device using a Diameter Base Protocol RAR signal.   The mobile communication method according to any one of claims 1 to 5, wherein, in the case of an emergency call, the call control node acquires location information of the mobile terminal before setting up a voice bearer. .   The mobile communication method according to any one of claims 1 to 6, wherein the location information is a cell ID, an area code, or a tracking area ID of the mobile terminal.   A policy control node that holds location information of a mobile terminal, and holds the location information acquired from the radio base station or the mobility management node after a bearer is established via a mobility management node, and the location A policy control node characterized by transmitting information to a call control node.   9. The policy control node according to claim 8, wherein the location information transmitted by a Diameter Base Protocol RAA signal is transmitted to the call control node by a Diameter Base Protocol RAR signal.   The policy control node according to claim 8 or 9, wherein an AAA signal of a Diameter Base Protocol corresponding to an AAR signal of the Diameter Base Protocol transmitted from the call control node is transmitted to the call control node.   11. The policy control node according to claim 10, wherein the acquisition request signal for the location information transmitted together with the AAR signal from the call control node is transmitted to the gateway device as a RAR signal of a Diameter Base Protocol.   The policy control node according to any one of claims 8 to 11, wherein the location information is a cell ID, area code, or tracking area ID of the mobile terminal.

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