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WO2018145671A1 - Cross-system handover method and device, and computer storage medium - Google Patents

Cross-system handover method and device, and computer storage medium Download PDF

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Publication number
WO2018145671A1
WO2018145671A1 PCT/CN2018/082149 CN2018082149W WO2018145671A1 WO 2018145671 A1 WO2018145671 A1 WO 2018145671A1 CN 2018082149 W CN2018082149 W CN 2018082149W WO 2018145671 A1 WO2018145671 A1 WO 2018145671A1
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WO
WIPO (PCT)
Prior art keywords
bearer information
amf
default
information
dedicated
Prior art date
Application number
PCT/CN2018/082149
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French (fr)
Chinese (zh)
Inventor
李振东
朱进国
梁爽
周晓云
Original Assignee
中兴通讯股份有限公司
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Publication of WO2018145671A1 publication Critical patent/WO2018145671A1/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/16Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]
    • H04W28/26Resource reservation
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W36/00Hand-off or reselection arrangements
    • H04W36/14Reselecting a network or an air interface
    • H04W36/144Reselecting a network or an air interface over a different radio air interface technology
    • H04W36/1443Reselecting a network or an air interface over a different radio air interface technology between licensed networks

Definitions

  • the present invention relates to the field of communications, and in particular, to a method and apparatus for switching between systems, and a computer storage medium.
  • the 3GPP (3rd Generation Partnership Project) has developed a fourth-generation (or LTE, Long Term Evolution, long-term evolution) mobile communication system from R8. Its network architecture is shown in Figure 1. The functions of each network element in the architecture are as follows:
  • the terminal is also called User Equipment (UE): accessing the 4G network through the wireless air interface and obtaining services.
  • UE User Equipment
  • the terminal exchanges information through the air interface and the eNB base station, and passes through the non-access stratum signaling NAS (non-Access Stratum) and the core.
  • NAS Non-Access Stratum
  • the mobility management entity of the network interacts with the information.
  • the base station e.g., the evolved base station RAN, radio access network, eNB
  • the base station is responsible for the air interface resource scheduling of the terminal accessing the network and the connection management of the air interface.
  • the core network control plane entity is mainly responsible for user authentication, authorization, and subscription checking, user mobility management, public data network (PDN) connection, and bearer maintenance. Triggering is triggered in the user IDLE state. Call and other functions.
  • S-GW Serving Gateway
  • PDN Gateway The core network user plane function entity is the access point of the terminal accessing the PDN network. It is responsible for allocating user IP addresses, network triggered bearer establishment, modification and deletion, and QoS control. The functions such as billing are the anchor points of the user in the 3GPP system, so as to ensure the IP address unchanged and ensure business continuity.
  • the P-GW is further divided into two parts, one is the control entity PGW-C, and the other is the user plane entity PGW-U.
  • PGW-C is responsible for signaling control
  • PGW-U is responsible for IP forwarding.
  • HSS Home Subscribed Server
  • PCRF Policy and charging control function
  • the PCRF provides network control rules based on service data flows, including traffic data flow detection, Gating Control, Quality of Service (QoS) control, and data flow based charging rules.
  • QoS Quality of Service
  • the PCRF sends its formulated policies and charging rules to the P-GW for execution.
  • next-generation communication system can support eMBB (Evolved Mobile Broadband), mMTC (Massive Machine Type Communication), uMTC (Ultra). Reliable Machine Type Communication, three types of services, which have different network characteristics.
  • eMBB Evolved Mobile Broadband
  • mMTC Massive Machine Type Communication
  • uMTC Ultra
  • Reliable Machine Type Communication three types of services, which have different network characteristics.
  • 2 is a schematic diagram of a next-generation mobile communication network architecture, in which the functions of each network element are as follows:
  • the terminal accesses the network through the next-generation wireless air interface and obtains the service.
  • the terminal exchanges information through the air interface and the base station, and interacts with the common control plane function of the core network and the session control plane through the non-access layer signaling. information.
  • the next-generation base station (NG RAN, Radio Access Network, gNB), that is, the NR base station, is responsible for the air interface resource scheduling of the terminal access network and the connection management of the air interface.
  • NG RAN Radio Access Network
  • gNB Radio Access Network
  • Session Management Function This is the session management function, which interacts with the terminal. It is mainly responsible for handling the establishment, modification, and deletion of User Protocol Data Unit (PDU) sessions. Selecting the User Plane function (UPF) User plane function); establish user plane connection between the UE and the UPF; and determine the quality of service (QoS) parameters of the session together with the Policy Control Function (PCF).
  • UPF User Plane function
  • QoS quality of service
  • Access and Mobility Control Function The access and mobility management functions are common control plane functions in the core network.
  • a user has only one AMF, which is responsible for authentication, authorization, and subscription checking of users to ensure that users are legitimate users; user mobility management, including location registration and temporary identity allocation; when users initiate PDUs (Packet Data Units)
  • PDUs Packet Data Units
  • the connection establishment request is made, the appropriate SMF is selected; the non-access stratum (NAS, Non Access Stratum) signaling between the UE and the SMF is forwarded; and the access stratum AS (Access Stratum) signaling between the base station and the SMF is forwarded.
  • the NAS message is sent and received between the UE and the AMCF through the N1 interface.
  • the AMCF interacts with the next-generation base station NG RAN through the N2 interface.
  • UPF User Plane Function
  • UPF Provides user plane processing functions, including data forwarding and QoS execution.
  • UPF also provides user plane anchors when users move to ensure business continuity.
  • the user plane function UPF and the generation base station NG RAN send and receive the media plane data of the UE through the N3 interface.
  • the SMF controls the UPF through the N4 interface.
  • PCF Policy Control Function
  • Subscription Data Management stores the user's subscription data, which is similar to the HSS in the 4G era.
  • NextGen System NextGen System
  • hotspots such as downtown, business centers and more.
  • the UE accesses the 5G system, as the user moves, the coverage of the 5G system is removed, and it is necessary to solve how to seamlessly switch to the 4G system, otherwise the session will be interrupted.
  • Figure 3 is a network architecture that satisfies 4G and 5G bidirectional switching.
  • the core feature is that the architecture is compatible with both 4G and 5G architectures.
  • PGW-C and SMF are combined into one.
  • PGW-U and UPF are combined into one.
  • PCF and PCRF are combined into one.
  • the user plane of UE is always anchored in UPF. /PGW-U.
  • an Nx interface is added, and an inter-system handover request is sent on the interface. In this way, when the UE switches between LTE and 5G, seamless handover can be guaranteed.
  • each bearer represents a corresponding service flows, and its QoS parameters.
  • the concept of QoS flow is adopted, and each QoS flow includes a corresponding QoS profile (ie, OoS configuration) and a packet filter.
  • the process of the user equipment switching from the 5G system to the 4G system occurs. It has been found that after the user equipment switches from 5G to 4G, the user equipment needs to be allocated a communication delay to be allocated resources for communication, so that data transmission can be realized, thereby causing the user equipment to switch from 5G to 4G. The delay is large and the data transmission delay after switching is large.
  • the embodiment of the invention provides a cross-system switching method and device, and a computer storage medium, which solves the problem that the switching delay of 5G to 4G is large or the data transmission delay after switching is large.
  • a cross-system handover method includes: a first access and mobility management function AMF learns that a user equipment UE cross-system handover occurs, where cross-system handover refers to a UE.
  • AMF learns that a user equipment UE cross-system handover occurs, where cross-system handover refers to a UE.
  • the first AMF is located in the 5G system; in the process of the UE switching from the 5G system to the 4G system, the first AMF will pre-save the UE
  • the target bearer information is sent to the mobility management node function MME, where the MME located in the 4G system is configured to reserve resources on the radio side for the UE according to the received target bearer information.
  • AMFAMFAMFAMFAMF provides a cross-system switching device according to another aspect of the present invention.
  • the device includes: a learning unit configured to learn that a user equipment UE cross-system handover occurs, where cross-system handover refers to the UE from the fifth
  • the mobile communication technology 5G system is switched to the 4th generation mobile communication technology 4G system
  • the first sending unit is configured to send the target bearer information of the pre-saved UE to the mobile management during the process of the UE switching from the 5G system to the 4G system.
  • the node function MME wherein the MME located in the 4G system is configured to reserve resources on the radio side for the UE according to the received target bearer information.
  • a cross-system switching apparatus comprising: a receiving unit configured to switch from a fifth generation mobile communication technology 5G system to a fourth generation mobile communication technology at a user equipment UE
  • the access bearer and the mobility management function receive the target bearer information of the UE sent by the first AMF, where the first AMF is located in the 5G system, and the reserved unit is configured to be the UE according to the received target bearer information.
  • an access and mobility management function module comprising: a first processor; a first memory configured to store first processor executable instructions; configured to be configured according to The first processor controls the first transmission device that performs the information transceiving communication; wherein the first processor is configured to perform the following operations: learning that the user equipment UE cross-system handover occurs, wherein the cross-system handover refers to the UE moving from the fifth generation
  • the communication technology 5G system is switched to the 4th generation mobile communication technology 4G system; in the process of the UE switching from the 5G system to the 4G system, the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the 4G system is located
  • the MME is configured to reserve resources on the radio side for the UE according to the received target bearer information.
  • the user equipment UE receives the target bearer information corresponding to the default QoS flow Default Qos Flow from the first access and mobility management function AMF in the fifth generation mobile communication technology 5G system, where the target bearer information is: Bearer information used by the UE after switching from the 5G system to the 4th generation mobile communication technology 4G system.
  • the receiving unit is configured to receive the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is in the slave 5G The bearer information used after the system switches to the 4G mobile communication technology 4G system.
  • a computer storage medium can be configured to store computer executable code that, when executed, is capable of implementing one or more of the foregoing technical solutions Cross-system switching method.
  • the first AMF of the access and mobility management function learns that the user equipment UE cross-system handover, wherein the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication.
  • the first AMF is located in the 5G system; in the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, where the 4G system is located
  • the MME is configured to reserve resources on the radio side for the UE according to the received target bearer information, thereby solving the problem that the wireless side cannot reserve resources for the user equipment due to the AMF failing to generate session information during cross-system handover in the related art.
  • a technical problem or a technical problem of delaying the resource reservation for the user equipment thereby solving the problem that the user equipment cannot obtain the resource for data transmission after switching from the 5G system to the 4G system in the prior art, for the user
  • This increases the rate of switching from a 5G system to a 4G system and increases the data transfer rate after switching from a 5G system to a 4G system.
  • FIG. 1 is a schematic diagram of a network architecture of a mobile communication system in the related art
  • FIG. 2 is a schematic diagram of a network architecture of a mobile communication system in the related art
  • FIG. 3 is a schematic diagram of a network architecture for 4G and 5G bidirectional handover in the related art
  • FIG. 4 is a schematic diagram of an alternative computer terminal in accordance with an embodiment of the present invention.
  • FIG. 5 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 6 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 7 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 8 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 9 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 10 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 11 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 12 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention.
  • FIG. 13 is a schematic diagram of an optional cross-system switching device in accordance with an embodiment of the present invention.
  • FIG. 14 is a schematic diagram of an alternative cross-system switching device in accordance with an embodiment of the present invention.
  • AMF is a network element unrelated to the session, and it has no session related data.
  • the MME must reserve resources in the wireless measurement (ie, the eNB side) according to the session related parameters (such as bearer information) received in the handover request. Therefore, in the embodiment of the present invention, if the user equipment switches from the 5G system to the 4G system, the AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, so that the MME can receive the target bearer information.
  • the resource is reserved for the user equipment, thereby improving the problem that the handover delay is large due to the inability of the UE to obtain resources or the resources of the 4G system are delayed, and the data transmission delay after the handover is large.
  • the method embodiment provided in Embodiment 1 of the present application can be executed in a mobile terminal, a computer terminal or the like. For example, running on a computer terminal, as shown in FIG.
  • the computer terminal may include one or more (only one shown) processor 401 (the processor 401 may include, but is not limited to, a microprocessor MCU or programmable A processing device such as a logic device FPGA, a memory 403 for storing data, and a transmission device 405 for communication functions. It will be understood by those skilled in the art that the structure shown in FIG. 4 is merely illustrative and does not limit the structure of the above electronic device.
  • the memory 403 can be configured as a software program and a module for storing application software, such as program instructions/modules corresponding to the control method of the device in the embodiment of the present invention, and the processor 401 executes by executing a software program and a module stored in the memory 403.
  • application software such as program instructions/modules corresponding to the control method of the device in the embodiment of the present invention
  • the processor 401 executes by executing a software program and a module stored in the memory 403.
  • the memory can include high speed random access memory and can also include non-volatile memory such as one or more magnetic storage devices, flash memory, or other non-volatile solid state memory.
  • the memory can further include memory remotely located relative to the processor, which can be connected to the computer terminal over a network. Examples of such networks include, but are not limited to, the Internet, intranets, local area networks, mobile communication networks, and combinations thereof.
  • the transmission device is for receiving or transmitting data via a network.
  • the above-described network specific examples may include a wireless network provided by a communication provider of a computer terminal.
  • the transmission device includes a Network Interface Controller (NIC) that can be connected to other network devices through the base station to communicate with the Internet.
  • NIC Network Interface Controller
  • access and mobility management function module and the mobility management node function module of the present application may be the foregoing computer terminals.
  • a method embodiment of a method of switching across systems is provided, it being noted that the steps illustrated in the flowchart of the figures may be performed in a computer system such as a set of computer executable instructions. Also, although logical sequences are shown in the flowcharts, in some cases the steps shown or described may be performed in a different order than the ones described herein.
  • FIG. 5 is a flowchart of an optional cross-system switching method according to an embodiment of the present invention. As shown in FIG. 5, the method includes the following steps:
  • Step S501 the first access and mobility management function AMF learns that the user equipment UE cross-system handover, and the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system, first The AMF is located in a 5G system.
  • Step S502 in the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, and the MME located in the 4G system is used to receive the target bearer according to the received target.
  • the information is that the UE reserves resources on the radio side.
  • the access and mobility management function first AMF learns that the user equipment UE cross-system handover, and the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system.
  • the first AMF is located in the 5G system; in the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, and the MME located in the 4G system uses
  • the received target bearer information is that the UE reserves resources on the radio side.
  • interfaces between the AMF and the MME such as S1-C, S11, Gx, N2, N3, Nx, S5-C, etc. communicate for the two network elements. interface.
  • the above method is a method of operating AMF in a 5G system.
  • the first AMF before the first AMF learns that the UE cross-system handover, receives and saves the default bearer information sent by the session control function SMF in the 5G system; the target bearer information includes at least the default bearer.
  • the information, the default bearer information is the bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow generated by the SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system.
  • the first AMF receives and saves the default bearer information sent by the session control function SMF in the 5G system, when the default quality of service flow changes, the first AMF receives the SMF.
  • the default bearer information that is retransmitted, where the default bearer information currently received by the first AMF is the bearer information corresponding to the changed default quality of service flow generated by the SMF when the default quality of service flow changes;
  • An AMF replaces the saved default bearer information with the currently received default bearer information.
  • the first AMF before the first AMF learns that the UE cross-system handover occurs, the first AMF receives and saves the dedicated bearer information sent by the SMF in the 5G system; the target bearer information includes default bearer information and a dedicated bearer.
  • the information, the dedicated bearer information is bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
  • the first AMF sends the saved target information of the UE to the second AMF, where the second AMF is used to save the target bearer information of the received UE. .
  • a method embodiment of a cross-system handover method is also provided, which is a method for running an MME in a 4G system.
  • the method includes:
  • Step S101 in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, the mobility management node function MME receives the access and mobility management function of the UE sent by the first AMF.
  • Target bearer information wherein the first AMF is located in the 5G system, and the MME is located in the 4G system;
  • Step S102 The MME reserves resources on the radio side for the UE according to the received target bearer information.
  • the mobility management node function MME receives the access and mobility management function sent by the first AMF.
  • Target bearer information of the UE where the first AMF is located in the 5G system, and the MME is located in the 4G system, and the MME reserves resources for the UE on the radio side according to the received target bearer information. Therefore, the technical problem that the wireless side cannot reserve resources for the user equipment caused by the AMF unable to generate session information during the cross-system handover in the related art is solved, and the technology for reserving resources for the user equipment on the wireless side during cross-system handover is realized. effect.
  • the MME receives the target bearer information of the UE that is sent by the first AMF, where the MME receives the default bearer information sent by the first AMF, where the target bearer information includes at least default bearer information, and the default bearer.
  • the information is bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow generated by the session control function SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system.
  • the MME receiving the target bearer information of the UE that is sent by the first AMF further includes: the MME receiving the dedicated bearer information sent by the first AMF, where the target bearer information includes default bearer information and dedicated bearer information,
  • the dedicated bearer information is bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
  • a cross-system handover method is provided.
  • the network side SMF When a UE establishes a PDU session (that is, a PDU session) in a 5G system, the network side SMF generates Bearer information corresponding to the deafault Qos flow (ie, bearer information). information). The SMF sends this information to the UE and the AMF for saving.
  • the network When a dedicated QoS flow is established for the UE in the 5G system, the network generates Bearer information corresponding to the QoS flow, and the SMF sends the information to the UE and the AMF for saving.
  • the AMF sends the saved bearer information to the MME.
  • the MME reserves resources on the radio side according to the bearer information.
  • the deafault Qos flow changes, the network updates the Bearer information corresponding to the deafault Qos flow, and the SMF sends the updated information to the UE and the AMF for saving.
  • the destination AMF ie, the switched AMF
  • the destination AMF obtains Bearer information in the 4G system corresponding to the saved QoS flow from the source AMF (AMF before handover).
  • a cross-system switching method including:
  • the user equipment UE receives the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is switched from the 5G system to the fourth Bearer information used after the mobile communication technology 4G system.
  • the AMF sends the target bearer information to the UE by using an RRC configuration request, and the UE may receive the information from the corresponding AMF.
  • the target carries information, thereby starting to perform switching of the 5G system to the 4G system, and the like.
  • the target bearer information is that the first AMF is received from the session management function SMF.
  • the target bearer information can be generated by the SMF.
  • the default bearer information is the same as the default quality of service flow generated by the SMF in the 4G system when the protocol data unit PDU session is established for the UE in the 5G system.
  • the bearer information of the default bearer; the dedicated bearer information is when the dedicated service quality stream (Dedicated Qos Flow) is established for the UE in the 5G system, and the SMF generates the corresponding service quality flow corresponding to the dedicated Bearer information of dedicated bearers in the 4G system.
  • the embodiment further provides a cross-system switching device, which can be applied to the UE, and includes:
  • the receiving unit is configured to receive the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is in the slave 5G The bearer information used after the system switches to the 4G mobile communication technology 4G system.
  • the receiving unit may be configured to receive the target bearer information from the first AMF during handover of the UE from the 5G system to the 4G system.
  • the switching device may further include: a storage unit, where the storage unit is configured to store the target bearer information.
  • the target bearer information is that the first AMF is received from the session management function SMF.
  • the target bearer information can be generated by the SMF.
  • the default bearer information is the same as the default quality of service flow generated by the SMF in the 4G system when the protocol data unit PDU session is established for the UE in the 5G system.
  • the bearer information of the default bearer; the dedicated bearer information is when the dedicated service quality stream (Dedicated Qos Flow) is established for the UE in the 5G system, and the SMF generates the corresponding service quality flow corresponding to the dedicated Bearer information of dedicated bearers in the 4G system.
  • FIG. 6 is an implementation manner of establishing a PDU session in an embodiment of the present invention.
  • Step S601 The terminal determines to initiate a new PDU session, and then initiates a PDU session establishment request, and the mobility NAS message sent by the UE to the AMF includes the session NAS message cell sent by the UE to the SMF.
  • the session NAS message cell has a PDU session type with a new request session, a selected SSC mode, etc., and an indication to support 5G and 4G IWK.
  • Step S602 the NG RAN sends a PDU session establishment request to the AMF.
  • Step S603 the AMF receives and parses the mobility NAS message, selects an appropriate SMF according to the information therein (that is, SMF/PGW-C in the present application), and saves the correspondence between the PDU session identifier and the selected SMF.
  • the AMF forwards the session NAS message, the data network name, and the user identity, PDU session ID to the selected SMF (ie, the send session establishment request is sent to the SMF).
  • Step S604 the SMF obtains the subscription data of the user from the SDM.
  • Step S605 the SMF checks the user subscription, determines whether the PDU session request is allowed, and determines the QoS information of the PDU session pre-authorization, which includes information (including QoS) of the default bearer of the UE when the 4G access is performed.
  • the optional SMF may also negotiate with the PCF to determine the default QoS information required for the PDU session, as well as the default bearer information (including QoS) for 4G access.
  • Step S606 The SMF selects an appropriate user plane function UPF according to the session information, and sends an N4 session establishment request to the selected UPF.
  • the message request includes the requested QoS and the like, and at least includes the QoS flow label and the corresponding uplink and downlink flows. template.
  • the UPF establishes an N4 session-related context, and stores the QoS information.
  • the UPF allocates the N3 tunnel uplink tunnel identifier of the session, and returns an N4 session establishment response to the SMF, where the UP3 allocates the N3 tunnel uplink tunnel identifier.
  • Step S607 the SMF acquires the tunnel identifier allocated by the UPF, and requests the base station to establish the radio resource of the session through the AMF.
  • the SMF sends a message to the AMF with the SM cell.
  • the cell includes the PDU session identifier, the QoS information of the session request, and the N3 tunnel uplink tunnel identifier assigned by the UPF to the session.
  • the SMF brings the information of the default QoS flow and the information of the default bearer of the UE during 4G access to the AMF, and the AMF stores the information (including QoS) of the default bearer when the 4G access is performed.
  • Step S608 the AMF sends an N2-AP radio resource setup request message to the base station. It contains the information of the default QoS flow received by the AMF and the default bearer information of the UE when it accesses the 4G.
  • Step S609 the base station allocates a radio resource according to the received QoS information, and interacts with the terminal to establish a wireless dedicated bearer of the session.
  • the radio resource control (RRC) configuration request message sent by the base station to the UE carries the information of the default QoS flow received from the AMF and the information of the default bearer of the UE when the 4G accesses.
  • the base station allocates an N3 tunnel downlink tunnel identifier.
  • Step S610 the terminal performs an RRC configuration response.
  • Step S611 the base station returns an N2-AP radio resource setup response message to the AMF, where the N3 tunnel downlink tunnel identifier is allocated by the base station, that is, as shown in FIG. 6, the NG RAM sends a radio resource setup response to the AMF.
  • Step S612 the AMF returns a radio resource setup response message to the SMF, where the N3 tunnel downlink tunnel identifier is allocated by the base station, that is, as shown in FIG. 6, the AMF sends a radio resource setup response to the SMF.
  • step S613 the SMF sends an N4 session update request to the UPF, and sends the N3 tunnel downlink tunnel identifier assigned by the base station to the User Plane Function (UPF).
  • UPF User Plane Function
  • Step S614 optionally, the AMF may also send the information of the default QoS flow and the information of the default bearer of the UE when the 4G access is sent to the UE by using the NAS message.
  • Step S615 the SMF returns a PDU session establishment response to the AMF, and the QoS information of the session includes at least a pre-authorized QoS flow identifier and a corresponding upstream template.
  • the information about the default QoS flow and the information about the default bearer of the UE when the 4G is accessed may be included, and the AMF stores the information of the default bearer when the 4G access is used as the transparent data.
  • Step S616 the AMF forwards the PDU session establishment response to the UE.
  • the terminal saves the information of the received default Qos flow and the default bearer information of the UE when accessing the 4G.
  • step S617 the PDU session is established, and the UE requests the network to allocate an IP address through the PDU session, and a new PDU session is established through the foregoing steps, and the terminal can send and receive uplink and downlink data through the PDU session.
  • FIG. 7 is a schematic diagram of an embodiment of establishing a PDU session in a Home Routed scenario according to an embodiment of the present invention.
  • Step S701 The terminal determines to initiate a new PDU session, and then initiates a PDU session establishment request, and the mobility NAS message sent by the UE to the AMF includes the session NAS message cell sent by the UE to the SMF.
  • the session NAS message cell has a PDU session type with a new request session, a selected SSC mode, etc., and an indication to support 5G and 4G IWK.
  • Step S702 the AMF receives and parses the mobility NAS message, selects an appropriate visited network V-SMF according to the information therein, and saves the correspondence between the PDU session identifier and the selected V-SMF.
  • the AMF forwards the session NAS message, the data network name, and the user ID and the PDU session identifier to the selected V-SMF, that is, sends a PDU session establishment request.
  • Step S703 an N4 session is established, and the V-SMF selects an appropriate user plane function V-UPF according to the session information, and sends an N4 session establishment request to the selected V-UPF.
  • the V-UPF allocates the N3 tunnel uplink tunnel identifier of the session, and the N9 tunnel downlink identifier, and returns it to the V-SMF.
  • Step S704 the V-SMF forwards the session NAS message (including the N9 tunnel downlink identifier) to the user's home network.
  • the user home network selects the appropriate H-SMF (also known as SMF/PGW-C in this application).
  • the H-SMF obtains the user's subscription data from the SDM. (Simplified period, not shown in the figure), that is, a PDU session establishment request is sent.
  • Step S705 The H-SMF checks the user subscription, determines whether the PDU session request is allowed, and determines the QoS information of the pre-authorization of the PDU session, where the information (including QoS) of the default bearer of the UE when the 4G access is included.
  • the optional SMF may also negotiate with the PCF to determine the default QoS information required for the PDU session, as well as the default bearer information (including QoS) for 4G access.
  • Step S706 The H-SMF selects an appropriate user plane function H-UPF according to the session information, and sends an N4 session establishment request to the selected H-UPF, where the message request carries information such as requested QoS, where at least the QoS flow label is included. And the corresponding uplink and downlink flow template, and the N9 tunnel downlink identifier.
  • the H-UPF establishes an N4 session-related context, and stores the QoS information.
  • the UPF allocates the N9 tunnel uplink tunnel identifier of the session, and returns an N4 session setup response to the SMF, where the N9 tunnel uplink tunnel identifier is allocated by the H-UPF.
  • Step S707 the radio resource request is established.
  • the H-SMF obtains the tunnel identifier assigned by the UPF, and requests the base station to establish the radio resource of the session through the V-SMF and the AMF.
  • the message is sent to the V-SMF, and includes the SM cell.
  • the cell includes the PDU session identifier, the QoS information of the session request, and the N9 tunnel uplink tunnel identifier allocated by the UPF for the session, and the V-SMF identifies the N9 tunnel uplink identifier. Replace with the N3 tunnel upstream identifier and forward the information to AMF.
  • the QoS information also includes information about the default bearer of the UE when the 4G is accessed.
  • Step S708 The V-SMF sends the message to the AMF, and the AMF saves the information (including QoS) of the default bearer when the 4G access is performed, that is, sends a radio resource request setup message.
  • Step S709 the AMF sends an N2-AP radio resource setup request message to the base station. It contains the information of the default QoS flow received by the AMF and the default bearer information of the UE when it accesses the 4G.
  • Step S710 The base station allocates a radio resource according to the received QoS information, and interacts with the terminal to establish a wireless dedicated bearer of the session.
  • the RRC configuration request message sent by the base station to the UE carries information about the default QoS flow received from the AMF and information about the default bearer of the UE when the 4G is accessed.
  • the base station allocates an N3 tunnel downlink tunnel identifier.
  • Step S711 returning an RRC configuration response message.
  • Step S712 the base station returns an N2-AP radio resource setup response message to the AMF, where the N3 tunnel downlink tunnel identifier allocated by the base station is carried.
  • Step S713 the AMF returns a radio resource setup response message to the V-SMF, where the N3 tunnel downlink tunnel identifier allocated by the base station is carried.
  • Step S714 The V-SMF sends an N4 session update request to the UPF, and sends the N3 tunnel downlink tunnel identifier allocated by the base station and the N9 tunnel uplink identifier allocated by the H-UPF to the V-UPF.
  • Step S715 the V-SMF forwards the radio resource setup response to the H-SMF.
  • Step S716 optionally, the AMF may also send the information of the default QoS flow and the information of the default bearer of the UE when the 4G access is sent to the UE by using the NAS message.
  • Step S717 The H-SMF returns a PDU session establishment response to the AMF, and the QoS information of the session includes at least a pre-authorized QoS flow identifier and a corresponding upstream template.
  • the information about the default QoS flow and the information about the default bearer of the UE when the 4G is accessed may be included, and the AMF stores the information of the default bearer when the 4G access is used as the transparent data. This message is forwarded to the AMF via the V-SMF.
  • the terminal saves the received pre-authorization QoS information and the information of the default bearer of the UE when the 4G accesses.
  • Step S719 the UE informs the AMF that the PUD session establishment is completed.
  • step S720 the AMF informs the H-SMF that the PUD session establishment is completed.
  • the UE requests the network to allocate an IP address through the PDU session, and a new PDU session is established through the foregoing steps, and the terminal can send and receive uplink and downlink data through the PDU session.
  • FIG. 8 is a diagram of an embodiment of QoS flow establishment and update in an embodiment of the present invention.
  • Step S801 an Application Function (AF) request requests a resource of a session from the PCF/PCRF.
  • AF Application Function
  • Step S802 the PCF/PCRF sends the information of the QoS flow of the UE to the SMF according to the policy, such as adding a new QoS flow, or updating an existing QoS flow. It also includes bearer information when the QoS flow is mapped to 4G access.
  • Step S803 the SMF/PGW-C updates the QoS flow information of the UPF/PGW-U, such as adding a new QoS flow, or updating the existing QoS flow, wherein the PGW-C updates the bearer information on the PGW-U.
  • Step S804 the SMF requests the base station to establish a radio resource of the session through the AMF.
  • the SMF sends a message to the AMF with the SM cell.
  • the cell includes the PDU session identifier, the QoS flow information of the session request, and the bearer information corresponding to the QoS flow of the UE when the 4G access is also brought to the AMF, AMF.
  • the information of the corresponding bearer information when the 4G access is saved.
  • Step S805 the AMF sends an N2-AP radio resource setup request message to the base station.
  • the information about the QoS flow received by the AMF and the corresponding bearer information when the UE accesses the 4G are included.
  • Step S806 the base station allocates a radio resource according to the received QoS information, and interacts with the terminal to establish or update a wireless dedicated bearer of the session.
  • the RRC message sent by the base station to the UE carries the information of the QoS flow received from the AMF and the bearer information corresponding to the UE when the 4G accesses.
  • Step S807 returning an RRC configuration response.
  • Step S808 the base station returns an N2-AP radio resource setup response message to the AMF.
  • Step S809 the AMF returns a radio resource setup response message to the SMF.
  • Step S810 optionally, the AMF may also send the information of the QoS flow and the bearer information corresponding to the UE during the 4G access to the UE by using the NAS message.
  • FIG. 9 is an embodiment of the default QoS flow information in the embodiment of the present invention.
  • step S901 the information of the default Qos flow is changed for various reasons, such as the PCF/PCRF notifying the SMF.
  • step S902 the SMF/PGW-C updates the default QoS flow information of the UPF/PGW-U.
  • the PGW-C may also need to update the default bearer information on the PGW-U.
  • Step S903 the SMF requests the base station to update the radio resource of the default QoS flow through the AMF.
  • the message sent by the SMF to the AMF carries the SM cell, and the cell includes the PDU session identifier, the default QoS flow information of the session request, and the default bearer information of the UE when the 4G access is also brought to the AMF, and the AMF updates its Previously, the corresponding default bearer information when 4G access is saved.
  • Step S904 the AMF sends an N2-AP radio resource update request message to the base station. It contains the information of the default QoS flow received by the AMF and the default bearer information of the UE when it accesses the 4G.
  • Step S905 the base station updates the radio resource according to the received QoS information, and interacts with the terminal to update the wireless dedicated bearer of the session.
  • the RRC message sent by the base station to the UE carries the information of the default QoS flow received from the AMF and the default bearer information corresponding to the UE when the 4G accesses. For example, the base station sends an RRC configuration request according to the QoS information.
  • Step S906 returning an RRC configuration response.
  • Step S907 the base station returns an N2-AP radio resource update response message to the AMF.
  • Step S908 the AMF returns a radio resource update response message to the SMF.
  • Step S909 optionally, the AMF may also send the information of the default QoS flow and the default bearer information of the UE during 4G access to the UE by using the NAS message.
  • FIG. 10 is an embodiment in which the UE moves in an idle state and an AMF change occurs.
  • Step S1001 The UE sends a NAS message, such as a Tracking Area Update (TAU), to the NG base station.
  • a NAS message such as a Tracking Area Update (TAU)
  • step S1002 the base station selects a new AMF (ie, tAMF) and forwards the NAS message to the tAMF.
  • a new AMF ie, tAMF
  • step S1003 the tAMF requests the context of the user from the sAMF.
  • Step S1004 the sAMF provides a context response, and the sAMF sends the security context of the UE, the session context (each PDU session information, including the SMF address, the PDU session ID, and the like) to the tAMF, where the 4G access corresponding to each PDU session is included.
  • the session context each PDU session information, including the SMF address, the PDU session ID, and the like
  • the tAMF where the 4G access corresponding to each PDU session is included.
  • Default bearer information each PDU session information, including the SMF address, the PDU session ID, and the like
  • Step S1005 The tAMF establishes, according to the received context, an N11 interface in the session and the corresponding SMF based on each PDU session.
  • step S1006 the SMF returns to establish an interface response.
  • Figure 11 is an embodiment of the UE moving in a connected state, with AMF changes occurring.
  • step S1101 the UE moves in the connect state, and the 5G base station determines that the handover needs to be initiated.
  • the NG RAN sends a handover request to the sAMF.
  • step S1102 the sAMF finds that the target 5G base station is out of range, and the sAMF selects a new AMF (that is, tSMF).
  • a handover request is sent to the tSMF.
  • the security context is included, and the session context (including the SMF address, PDU session ID, etc. for each PDU session) is sent to the tAMF, which includes the default bearer information for each PDU session at the time of 4G access, and Optionally, the dedicated bearer information corresponding to the normal QoS flow.
  • Step S1103 The tAMF establishes an N11 interface in the session and the corresponding SMF based on the received context based on the received PDU session.
  • step S1104 the SMF returns a setup response.
  • step S1105 the tAMF requests the target side base station to reserve resources.
  • step S1106 the tAMF returns a handover request response to the sAMF.
  • FIG. 12 is a schematic flowchart of switching from 5G to 4G in the embodiment of the present invention.
  • the UE initiates a PDU session establishment process.
  • the UE attaches to the NG system and establishes a PDU session.
  • step S1201 the NG base station (NR RAN) determines that the handover needs to be initiated, and the NG RAN sends a handover request to the AMF.
  • step S1202 the AMF determines to switch from 5G to the 4G system, and sends a handover request to the MME.
  • the SMF address, the APN, and the corresponding bearer information of the stored UE when the 4G access is used (refer to the foregoing embodiment), where at least the default bearer information is included, optionally, may also include Dedicated bearer information.
  • Step S1203 The MME selects a suitable S-GW to send a create session request (session generation request) according to the received session information.
  • Step S1204 Send a handover preparation request, and the MME requests the E-UTRAN to establish a default bearer resource according to the received session information. Each session must establish a corresponding default bearer resource.
  • Step S1205 The E-UTRAN reserves the radio resources required for the UE to access the radio side, and returns a handover preparation request response message with reserved radio resource information.
  • the message also carries the S1-U downlink tunnel identifier assigned by the destination base station 2 for each PDN Connection that is successfully reserved.
  • Step S1206 The MME returns a handover request response to the AMF, where the radio resource information of the target base station is included.
  • Step S1207 the AMF returns a handover request response message to the NG base station, with the radio resource information reserved by the destination base station (E-UTRAN base station) for these PDU sessions.
  • Step S1208 The NG base station sends a handover command to the UE, with the radio resource information reserved by the destination base station.
  • Step S1209 The user equipment UE accesses from the 4G base station.
  • step S1210 the eNB sends a handover complete message to the MME.
  • Steps S1211 to S1215 are the same as the existing 4G cross-MME switching technology, and are simply described here.
  • Step S1211 The MME sends a session update request to the S-GW, where the S1-U downlink tunnel identifier is carried.
  • Step S1212 The S-GW sends a session update request to the PGW-C, where the media information of the S-GW is also carried.
  • step S1213 PGW-C and PGW-U interact to allocate media plane resources.
  • Step S1214 the PGW-C returns a response to the session update request to the S-GW, where the media information of the PGW-U is carried.
  • step S1215 the S-GW returns a response to the session update (ie, a session update response) to the MME; at this time, the UE can send/receive uplink and downlink data on the default bearer of the 4G PDN connection.
  • the session update ie, a session update response
  • step S1216 the MME sends a handover completion indication to the AMF.
  • step S1217 the AMF releases the N2 interface of the NG base station.
  • the P-GW then initiates the activation process for the remaining dedicated bearers.
  • an optional implementation manner is: if the default bearer information is included in the handover request sent by the AMF to the MME in step S1202, and the 4G dedicated bearer information corresponding to the QoS flow is included, then in step S1204, The MME not only requests the default bearer resource, but also requests the dedicated bearer resource. At this time, the P-GW is not required to initiate the activation process of the remaining dedicated bearers.
  • the method according to the above embodiment can be implemented by means of software plus a necessary general hardware platform, and of course, by hardware, but in many cases, the former is A better implementation.
  • the technical solution of the present invention which is essential or contributes to the prior art, may be embodied in the form of a software product stored in a storage medium (such as ROM/RAM, disk,
  • the optical disc includes a number of instructions for causing a terminal device (which may be a cell phone, a computer, a server, or a network device, etc.) to perform the methods described in various embodiments of the present invention.
  • a cross-system switching device is also provided in the embodiment of the present invention.
  • the device is used to implement the above embodiments and preferred embodiments, and the description thereof has been omitted.
  • the term "module” may implement a combination of software and/or hardware of a predetermined function.
  • the apparatus described in the following embodiments is preferably implemented in software, hardware, or a combination of software and hardware, is also possible and contemplated.
  • the apparatus may include: a learning unit 131 and a first transmitting unit 132.
  • the learning unit 131 is configured to learn that the user equipment UE cross-system handover, wherein the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system;
  • the first sending unit 132 is configured to send the information to the mobility management node function MME, where the MME located in the 4G system is configured to reserve resources for the UE on the radio side according to the received target bearer information.
  • the learning unit knows that the user equipment UE cross-system handover, wherein the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system; the first sending unit is in the UE.
  • the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the MME located in the 4G system is configured to use the target bearer information as the UE on the radio side.
  • Reserve resources
  • the above device can be applied to AMF in a 5G system.
  • the apparatus further includes: a first saving unit, configured to receive and save default bearer information sent by the session control function SMF in the 5G system before learning that the UE cross-system handover occurs; wherein the target bearer information At least the default bearer information is used.
  • the SMF In the process of establishing a protocol data unit PDU session for the UE in the 5G system, the SMF generates the default service quality flow Default Qos Flow corresponding to the PDU session and is used in the 4G system. Bearer information.
  • the first saving unit includes: an information receiving module, configured to receive the default bearer information resent by the SMF after receiving and saving the default bearer information sent by the session control function SMF in the 5G system, where the information receiving The default bearer information currently received by the module is the bearer information corresponding to the changed default quality of service flow generated by the SMF when the default QoS flow changes; the replacement module is used to replace the saved default bearer information. Is the default bearer information currently received.
  • the apparatus further includes: a second saving unit configured to receive and save the dedicated bearer information sent by the SMF in the 5G system before learning that the UE cross-system handover occurs; wherein the target bearer information includes The default bearer information and the dedicated bearer information are bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
  • a second saving unit configured to receive and save the dedicated bearer information sent by the SMF in the 5G system before learning that the UE cross-system handover occurs; wherein the target bearer information includes The default bearer information and the dedicated bearer information are bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
  • the apparatus further includes: a second sending unit configured to: when the UE is switched by the access and mobility management function in the 5G system, the first AMF to the second AMF, the UE to be saved The target bearer information is sent to the second AMF, where the second AMF is used to save the target bearer information of the received UE.
  • a second sending unit configured to: when the UE is switched by the access and mobility management function in the 5G system, the first AMF to the second AMF, the UE to be saved The target bearer information is sent to the second AMF, where the second AMF is used to save the target bearer information of the received UE.
  • a cross-system switching device is also provided in the embodiment of the present invention.
  • the device is used to implement the above embodiments and preferred embodiments, and the description thereof has been omitted.
  • the term "module” may implement a combination of software and/or hardware of a predetermined function.
  • the apparatus described in the following embodiments is preferably implemented in software, hardware, or a combination of software and hardware, is also possible and contemplated.
  • the apparatus may include: a receiving unit 141 and a reservation unit 142.
  • the receiving unit 141 is configured to receive, in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, the target bearer of the UE sent by the first AMF of the access and mobility management function. Information, wherein the first AMF is located in the 5G system;
  • the reservation unit 142 is configured to reserve resources on the radio side for the UE according to the received target bearer information.
  • the receiving unit receives the target of the UE sent by the first AMF of the access and mobility management function in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system.
  • Carrying information, the first AMF is located in the 5G system; the reservation unit reserves resources for the UE on the radio side according to the received target bearer information. Therefore, the technical problem that the wireless side cannot reserve resources for the user equipment caused by the AMF unable to generate session information during the cross-system handover in the related art is solved, and the technology for reserving resources for the user equipment on the wireless side during cross-system handover is realized. effect.
  • the receiving unit includes: a first receiving module, configured to receive default bearer information sent by the first AMF; where the target bearer information includes at least default bearer information, where the default bearer information is established for the UE in the 5G system.
  • the session control function SMF generates bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  • the receiving unit further includes: a second receiving module, configured to receive the dedicated bearer information sent by the first AMF; wherein the target bearer information includes default bearer information and dedicated bearer information, where the dedicated bearer information is in the 5G system.
  • the bearer When the UE establishes a dedicated quality of service stream (Dedicated Qos Flow), the bearer generates the bearer information used in the 4G system corresponding to the dedicated quality of service stream.
  • a dedicated quality of service stream Dedicated Qos Flow
  • each of the above modules may be implemented by software or hardware.
  • the foregoing may be implemented by, but not limited to, the foregoing modules are all located in the same processor; or, the above modules are in any combination.
  • the forms are located in different processors.
  • Embodiments of the present invention also provide a computer storage medium, which may be simply referred to as a storage medium.
  • a storage medium may be configured to store computer executable code such as program code and application program for performing the following steps:
  • the user equipment UE cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system;
  • the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the MME located in the 4G system is configured to follow the received target bearer information.
  • the UE reserves resources on the radio side.
  • the storage medium is further arranged to store program code for performing the following steps:
  • the foregoing storage medium may include, but not limited to, a USB flash drive, a Read-Only Memory (ROM), a Random Access Memory (RAM), a mobile hard disk, and a magnetic memory.
  • ROM Read-Only Memory
  • RAM Random Access Memory
  • the storage medium is a non-transitory storage medium.
  • the processor performs, according to the stored program code in the storage medium, that the user equipment UE is involved in cross-system handover, where the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system.
  • the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system.
  • the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the MME located in the 4G system is used
  • the UE reserves resources on the radio side according to the received target bearer information.
  • the processor performs, according to the stored program code in the storage medium, in a process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, And receiving, by the access and mobility management function, the target bearer information of the UE sent by the first AMF, where the first AMF is located in the 5G system; and the UE reserves resources on the radio side according to the received target bearer information.
  • modules or steps of the present invention described above can be implemented by a general-purpose computing device that can be centralized on a single computing device or distributed across a network of multiple computing devices. Alternatively, they may be implemented by program code executable by the computing device such that they may be stored in the storage device by the computing device and, in some cases, may be different from the order herein.
  • the steps shown or described are performed, or they are separately fabricated into individual integrated circuit modules, or a plurality of modules or steps thereof are fabricated as a single integrated circuit module.
  • the invention is not limited to any specific combination of hardware and software.
  • the AMF of the 5G system sends the target bearer information to the MME of the 4G system, and after the target bearer system received by the 4G system, The user equipment can be successfully reserved for the user equipment. After the user equipment switches to the 4G system, the reserved resources can be used for communication, thereby solving the problem that the user equipment switches from the 5G system to the 4G system in the prior art because no target bearer information is equal to the session.
  • the technical solution provided by the embodiment of the present invention has the characteristics of high speed and the like.

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Abstract

Provided in the embodiments of the present invention are a method and a device for cross-system handover, the method comprising: a first access and mobility management function (AMF) learns that a UE has undergone cross-system handover, said cross-system handover being from a 5G system to a 4G system, and said first AMF being within the 5G system; during the process of handover from a 5G system to a 4G system, the first AMF sends pre-stored target carrier information of the UE to a mobility management node function (MME), said MME, which is within the 4G system, being used for reserving resources for the UE on the radio side according to the received target carrier information. The embodiments of the present invention also provide a computer storage medium.

Description

跨系统的切换方法和装置、计算机存储介质Cross-system switching method and device, computer storage medium 技术领域Technical field
本发明涉及通信领域,尤其涉及一种跨系统的切换方法和装置、计算机存储介质。The present invention relates to the field of communications, and in particular, to a method and apparatus for switching between systems, and a computer storage medium.
背景技术Background technique
3GPP(3rd Generation Partnership Project)从R8开始制定第四代(或称LTE,Long Term Evolution,长期演进)移动通信系统。其网络架构如图1所示,架构中各网元的功能如下:The 3GPP (3rd Generation Partnership Project) has developed a fourth-generation (or LTE, Long Term Evolution, long-term evolution) mobile communication system from R8. Its network architecture is shown in Figure 1. The functions of each network element in the architecture are as follows:
终端又称为用户设备(UE,User Equipment):主要通过无线空口接入4G网络并获得服务,终端通过空口和eNB基站交互信息,通过非接入层信令NAS(non-Access Stratum)和核心网的移动性管理实体交互信息。The terminal is also called User Equipment (UE): accessing the 4G network through the wireless air interface and obtaining services. The terminal exchanges information through the air interface and the eNB base station, and passes through the non-access stratum signaling NAS (non-Access Stratum) and the core. The mobility management entity of the network interacts with the information.
基站(例如,无线接入网的演进型基站RAN,Radio Access Network,eNB):负责终端接入网络的空口资源调度和以及空口的连接管理。The base station (e.g., the evolved base station RAN, radio access network, eNB) of the radio access network is responsible for the air interface resource scheduling of the terminal accessing the network and the connection management of the air interface.
移动管理实体:核心网控制面实体,主要负责对用户的鉴权、授权以及签约检查,用户移动性管理,公共数据网络(Public Data Network,PDN)连接以及承载的维护,用户IDLE状态下触发寻呼等功能。Mobile management entity: The core network control plane entity is mainly responsible for user authentication, authorization, and subscription checking, user mobility management, public data network (PDN) connection, and bearer maintenance. Triggering is triggered in the user IDLE state. Call and other functions.
服务网关(Serving Gateway,S-GW):核心网用户面功能实体,主要负责漫游情况下和PDN GW的交互。Serving Gateway (S-GW): The functional entity of the core network user plane, which is mainly responsible for the interaction with the PDN GW in the case of roaming.
分组数据网关(PDN Gateway,P-GW):核心网用户面功能实体,是终端接入PDN网络的接入点,负责分配用户IP地址,网络触发的承载建立、修改和删除,还具有QoS控制计费等功能,是用户在3GPP系统内的锚点,从而保证IP地址不变,保证业务连续性。在控制与转发分离架构中,P-GW又分为2个部分,一个是控制实体PGW-C,一个是用户面实体PGW-U。PGW-C负责信令控制,PGW-U负责IP转发。PDN Gateway (P-GW): The core network user plane function entity is the access point of the terminal accessing the PDN network. It is responsible for allocating user IP addresses, network triggered bearer establishment, modification and deletion, and QoS control. The functions such as billing are the anchor points of the user in the 3GPP system, so as to ensure the IP address unchanged and ensure business continuity. In the control and forwarding separation architecture, the P-GW is further divided into two parts, one is the control entity PGW-C, and the other is the user plane entity PGW-U. PGW-C is responsible for signaling control, and PGW-U is responsible for IP forwarding.
归属签约服务器(HSS,Home Subscription Server):存储了用户的 签约信息。Home Subscribed Server (HSS): Stores the user's subscription information.
策略控制与计费规则功能(PCRF,Policy and charging control function),负责策略决策和计费规则的制定。PCRF提供了基于业务数据流的网络控制规则,这些网络控制包括业务数据流的检测、门控(Gating Control)、服务质量(Quality of Service,QoS)控制以及基于数据流的计费规则等。PCRF将其制定的策略和计费规则发送给P-GW执行。Policy and charging control function (PCRF), responsible for policy decision making and charging rules. The PCRF provides network control rules based on service data flows, including traffic data flow detection, Gating Control, Quality of Service (QoS) control, and data flow based charging rules. The PCRF sends its formulated policies and charging rules to the P-GW for execution.
3GPP从标准R14开始研究下一代通讯系统(Next Generation System),下一代通讯系统能够支持eMBB(Evolved Mobile Broadband,演进的移动宽带)、mMTC(Massive Machine Type Communication,超大连接机器通讯)、uMTC(Ultra Reliable Machine Type Communication,超可靠机器通讯)三种业务类型,这三种业务类型具有不同的网络特性。图2是下一代移动通信网络架构示意图,其中各网元的功能如下:3GPP began researching the Next Generation System from the standard R14. The next-generation communication system can support eMBB (Evolved Mobile Broadband), mMTC (Massive Machine Type Communication), uMTC (Ultra). Reliable Machine Type Communication, three types of services, which have different network characteristics. 2 is a schematic diagram of a next-generation mobile communication network architecture, in which the functions of each network element are as follows:
终端(UE,User Equipment),主要通过下一代无线空口接入网络并获得服务,终端通过空口和基站交互信息,通过非接入层信令和核心网的公共控制面功能以及会话控制面功能交互信息。The terminal (UE, User Equipment) accesses the network through the next-generation wireless air interface and obtains the service. The terminal exchanges information through the air interface and the base station, and interacts with the common control plane function of the core network and the session control plane through the non-access layer signaling. information.
下一代基站(NG RAN,Radio Access Network,gNB),也即NR基站,负责终端接入网络的空口资源调度和以及空口的连接管理。The next-generation base station (NG RAN, Radio Access Network, gNB), that is, the NR base station, is responsible for the air interface resource scheduling of the terminal access network and the connection management of the air interface.
会话控制面功能(SMF,Session Management Function):也即会话管理功能,和终端交互,主要负责处理用户协议数据单元(Packet Data Unit,PDU)会话建立、修改和删除请求,选择UPF(User Plane function,用户面功能);建立UE到UPF之间的用户面连接;和策略控制功能(Policy Control Function,PCF)一起确定会话的服务质量(Quality of Service,QoS)参数等功能。Session Management Function (SMF): This is the session management function, which interacts with the terminal. It is mainly responsible for handling the establishment, modification, and deletion of User Protocol Data Unit (PDU) sessions. Selecting the User Plane function (UPF) User plane function); establish user plane connection between the UE and the UPF; and determine the quality of service (QoS) parameters of the session together with the Policy Control Function (PCF).
接入和移动性控制功能(AMF,Access and Mobility control Function):也即接入和移动性管理功能,是核心网内的公共控制面功能。一个用户只有一个AMF,其负责对用户的鉴权、授权以及签约检查以保证用户是合法用户;用户移动性管理,包括位置注册和临时标识分配;当用户发起PDU(Packet Data Unit,分组数据单元)连接建立请求的时候,选择合适的SMF;转发UE和SMF之间的非接入层(NAS,Non Access Stratum)信令; 转发基站和SMF之间的接入层AS(Access Stratum)信令。UE和AMCF之间,通过N1接口发送、接受NAS消息。AMCF通过N2接口,和下一代基站NG RAN交互。Access and Mobility Control Function (AMF): The access and mobility management functions are common control plane functions in the core network. A user has only one AMF, which is responsible for authentication, authorization, and subscription checking of users to ensure that users are legitimate users; user mobility management, including location registration and temporary identity allocation; when users initiate PDUs (Packet Data Units) When the connection establishment request is made, the appropriate SMF is selected; the non-access stratum (NAS, Non Access Stratum) signaling between the UE and the SMF is forwarded; and the access stratum AS (Access Stratum) signaling between the base station and the SMF is forwarded. . The NAS message is sent and received between the UE and the AMCF through the N1 interface. The AMCF interacts with the next-generation base station NG RAN through the N2 interface.
用户面功能(UPF,User Plane Function):提供用户面处理功能,包括数据转发、QoS执行。UPF还提供用户移动时候的用户面锚点,保证业务连续性。用户面功能UPF和一代基站NG RAN之间,通过N3接口发送、接受UE的媒体面数据。SMF通过N4接口控制UPF。User Plane Function (UPF): Provides user plane processing functions, including data forwarding and QoS execution. UPF also provides user plane anchors when users move to ensure business continuity. The user plane function UPF and the generation base station NG RAN send and receive the media plane data of the UE through the N3 interface. The SMF controls the UPF through the N4 interface.
策略控制功能(PCF,Policy Control Function):向提供SMF提供用户的QoS rule(服务质量相关的规则)。Policy Control Function (PCF): Provides the user with the QoS rule (Quality of Service Related Rules) provided to the SMF.
签约数据管理功能(SDM,Subscription Data management):存储了用户的签约数据,其和4G时代的HSS类似。Subscription Data Management (SDM): stores the user's subscription data, which is similar to the HSS in the 4G era.
NextGen System(5G)的部署,开始会在热点地区局部部署,如市中心,商业中心等。当UE接入5G系统中,随着用户的移动,移除了5G系统的覆盖范围,必须要解决如何无缝的切换到4G系统中,否则会话会产生中断。The deployment of NextGen System (5G) will begin to be deployed locally in hotspots such as downtown, business centers and more. When the UE accesses the 5G system, as the user moves, the coverage of the 5G system is removed, and it is necessary to solve how to seamlessly switch to the 4G system, otherwise the session will be interrupted.
图3是一个满足4G与5G双向切换的网络架构。其核心特点是该架构同时兼容4G和5G架构,PGW-C和SMF合二为一,PGW-U和UPF合二为一,PCF和PCRF合二为一,UE的用户面始终锚定在UPF/PGW-U上。在AMF和MME之间,增加Nx接口,在该接口上发送跨系统间切换请求。这样UE在LTE和5G之间切换时,能够保证无缝切换。Figure 3 is a network architecture that satisfies 4G and 5G bidirectional switching. The core feature is that the architecture is compatible with both 4G and 5G architectures. PGW-C and SMF are combined into one. PGW-U and UPF are combined into one. PCF and PCRF are combined into one. The user plane of UE is always anchored in UPF. /PGW-U. Between the AMF and the MME, an Nx interface is added, and an inter-system handover request is sent on the interface. In this way, when the UE switches between LTE and 5G, seamless handover can be guaranteed.
当4G系统中,UE和网络使用bearer(承载概念),每个承载代表了对应的业务流(Service flows),及其QoS参数。在5G系统中,则采用QoS flow的概念,每个QoS flow包括了对应的QoS profile(即OoS配置)和分组过滤器(packet filter)。In a 4G system, the UE and the network use bearers (bearer concepts), each bearer represents a corresponding service flows, and its QoS parameters. In the 5G system, the concept of QoS flow is adopted, and each QoS flow includes a corresponding QoS profile (ie, OoS configuration) and a packet filter.
在网络的应用过程中,若用户设备移动到5G覆盖效果不太理想或没有5G网络覆盖的位置处,则会发生用户设备从5G系统向4G系统切换的过程。实践发现,用户设备从5G切换到4G之后,用户设备需要经历一段时延之后才会被分配通信用的资源,才能实现数据传输,从而对于用户而言导致用户设备从5G到4G的切换,切换延时大及切换后的数据传输延时大等问 题。In the application process of the network, if the user equipment moves to a location where the 5G coverage is not ideal or there is no 5G network coverage, the process of the user equipment switching from the 5G system to the 4G system occurs. It has been found that after the user equipment switches from 5G to 4G, the user equipment needs to be allocated a communication delay to be allocated resources for communication, so that data transmission can be realized, thereby causing the user equipment to switch from 5G to 4G. The delay is large and the data transmission delay after switching is large.
发明内容Summary of the invention
本发明实施例提供了一种跨系统的切换方法和装置、计算机存储介质,解决5G到4G的切换延时大或切换后的数据传输延时大的问题。The embodiment of the invention provides a cross-system switching method and device, and a computer storage medium, which solves the problem that the switching delay of 5G to 4G is large or the data transmission delay after switching is large.
根据本发明实施例的一个方面,提供了一种跨系统的切换方法,该方法包括:第一接入和移动性管理功能AMF获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统,第一AMF位于5G系统中;在UE从5G系统切换至4G系统的过程中,第一AMF将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。According to an aspect of the embodiments of the present invention, a cross-system handover method is provided. The method includes: a first access and mobility management function AMF learns that a user equipment UE cross-system handover occurs, where cross-system handover refers to a UE. Switching from the 5th generation mobile communication technology 5G system to the 4th generation mobile communication technology 4G system, the first AMF is located in the 5G system; in the process of the UE switching from the 5G system to the 4G system, the first AMF will pre-save the UE The target bearer information is sent to the mobility management node function MME, where the MME located in the 4G system is configured to reserve resources on the radio side for the UE according to the received target bearer information.
AMFAMFAMFAMFAMF根据本发明实施例的另一个方面,提供了一种跨系统的切换装置,该装置包括:获知单元,配置为获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;第一发送单元,配置为在UE从5G系统切换至4G系统的过程中,将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。AMFAMFAMFAMFAMF provides a cross-system switching device according to another aspect of the present invention. The device includes: a learning unit configured to learn that a user equipment UE cross-system handover occurs, where cross-system handover refers to the UE from the fifth The mobile communication technology 5G system is switched to the 4th generation mobile communication technology 4G system; the first sending unit is configured to send the target bearer information of the pre-saved UE to the mobile management during the process of the UE switching from the 5G system to the 4G system. The node function MME, wherein the MME located in the 4G system is configured to reserve resources on the radio side for the UE according to the received target bearer information.
根据本发明实施例的另一个方面,提供了一种跨系统的切换装置,该装置包括:接收单元,配置为在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,其中,第一AMF位于5G系统中;预留单元,配置为按照接收到的目标承载信息为UE在无线侧预留资源。According to another aspect of the present invention, a cross-system switching apparatus is provided, the apparatus comprising: a receiving unit configured to switch from a fifth generation mobile communication technology 5G system to a fourth generation mobile communication technology at a user equipment UE In the process of the 4G system, the access bearer and the mobility management function receive the target bearer information of the UE sent by the first AMF, where the first AMF is located in the 5G system, and the reserved unit is configured to be the UE according to the received target bearer information. Reserve resources on the wireless side.
根据本发明实施例的另一个方面,提供了一种接入和移动性管理功能模块,该模块包括:第一处理器;配置为存储第一处理器可执行指令的第 一存储器;配置为根据第一处理器的控制进行信息收发通信的第一传输装置;其中,第一处理器配置为执行以下操作:获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;在UE从5G系统切换至4G系统的过程中,将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。According to another aspect of the embodiments of the present invention, an access and mobility management function module is provided, the module comprising: a first processor; a first memory configured to store first processor executable instructions; configured to be configured according to The first processor controls the first transmission device that performs the information transceiving communication; wherein the first processor is configured to perform the following operations: learning that the user equipment UE cross-system handover occurs, wherein the cross-system handover refers to the UE moving from the fifth generation The communication technology 5G system is switched to the 4th generation mobile communication technology 4G system; in the process of the UE switching from the 5G system to the 4G system, the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the 4G system is located The MME is configured to reserve resources on the radio side for the UE according to the received target bearer information.
根据本发明实施例提供的另一种跨系统的切换方法,包括:Another cross-system switching method according to an embodiment of the present invention includes:
用户设备UE在第五代移动通讯技术5G系统中,从第一接入和移动性管理功能AMF接收与缺省服务质量流Default Qos Flow对应的目标承载信息,其中,所述目标承载信息为:所述UE在从5G系统切换到第四代移动通讯技术4G系统后使用的承载信息。The user equipment UE receives the target bearer information corresponding to the default QoS flow Default Qos Flow from the first access and mobility management function AMF in the fifth generation mobile communication technology 5G system, where the target bearer information is: Bearer information used by the UE after switching from the 5G system to the 4th generation mobile communication technology 4G system.
根据本发明实施例提供的再一种跨系统的切换装置,包括:A further cross-system switching device according to an embodiment of the invention includes:
接收单元,配置为用户设备UE在第五代移动通讯技术5G系统中,接收与缺省服务质量流Default Qos Flow对应的目标承载信息,其中,所述目标承载信息为:所述UE在从5G系统切换到第四代移动通讯技术4G系统后使用的承载信息。The receiving unit is configured to receive the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is in the slave 5G The bearer information used after the system switches to the 4G mobile communication technology 4G system.
根据本发明的另一个实施例,提供了一种计算机存储介质,计算机存储介质可以被设置为存储有计算机可执行代码,该计算机可执行代码被执行后,能够实现前述一个或多个技术方案提供的跨系统的切换方法。In accordance with another embodiment of the present invention, a computer storage medium is provided that can be configured to store computer executable code that, when executed, is capable of implementing one or more of the foregoing technical solutions Cross-system switching method.
在本发明实施例中,接入和移动性管理功能第一AMF获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统,第一AMF位于5G系统中;在UE从5G系统切换至4G系统的过程中,第一AMF将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源,从而解决了相关技术中在跨 系统切换时由于AMF不能生成会话信息导致的无线侧不能为用户设备预留资源的技术问题或迟迟不为用户设备预留资源的技术问题,进而解决了现有技术中用户设备从5G系统切换到4G系统之后,迟迟无法获取到资源进行数据传输的问题,对于用户而言从而提升了从5G系统切换到4G系统的速率,提升了从5G系统切换到4G系统之后的数据传输速率。In the embodiment of the present invention, the first AMF of the access and mobility management function learns that the user equipment UE cross-system handover, wherein the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication. In the technology 4G system, the first AMF is located in the 5G system; in the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, where the 4G system is located The MME is configured to reserve resources on the radio side for the UE according to the received target bearer information, thereby solving the problem that the wireless side cannot reserve resources for the user equipment due to the AMF failing to generate session information during cross-system handover in the related art. A technical problem or a technical problem of delaying the resource reservation for the user equipment, thereby solving the problem that the user equipment cannot obtain the resource for data transmission after switching from the 5G system to the 4G system in the prior art, for the user This increases the rate of switching from a 5G system to a 4G system and increases the data transfer rate after switching from a 5G system to a 4G system.
附图说明DRAWINGS
此处所说明的附图用来提供对本发明的进一步理解,构成本申请的一部分,本发明的示意性实施例及其说明用于解释本发明,并不构成对本发明的不当限定。在附图中:The drawings described herein are intended to provide a further understanding of the invention, and are intended to be a part of the invention. In the drawing:
图1是相关技术中移动通信系统的网络架构的示意图;1 is a schematic diagram of a network architecture of a mobile communication system in the related art;
图2是相关技术中移动通信系统的网络架构的示意图;2 is a schematic diagram of a network architecture of a mobile communication system in the related art;
图3是相关技术中用于4G与5G双向切换的网络架构的示意图;3 is a schematic diagram of a network architecture for 4G and 5G bidirectional handover in the related art;
图4是根据本发明实施例的一种可选的计算机终端的示意图;4 is a schematic diagram of an alternative computer terminal in accordance with an embodiment of the present invention;
图5是根据本发明实施例的可选的跨系统的切换方法的流程图;5 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图6是根据本发明实施例的可选的跨系统的切换方法的流程图;6 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图7是根据本发明实施例的可选的跨系统的切换方法的流程图;7 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图8是根据本发明实施例的可选的跨系统的切换方法的流程图;8 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图9是根据本发明实施例的可选的跨系统的切换方法的流程图;9 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图10是根据本发明实施例的可选的跨系统的切换方法的流程图;10 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图11是根据本发明实施例的可选的跨系统的切换方法的流程图;11 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图12是根据本发明实施例的可选的跨系统的切换方法的流程图;12 is a flow chart of an alternative cross-system handover method in accordance with an embodiment of the present invention;
图13是根据本发明实施例的可选的跨系统的切换装置的示意图;13 is a schematic diagram of an optional cross-system switching device in accordance with an embodiment of the present invention;
图14是根据本发明实施例的可选的跨系统的切换装置的示意图。14 is a schematic diagram of an alternative cross-system switching device in accordance with an embodiment of the present invention.
具体实施方式detailed description
下文中将参考附图并结合实施例来详细说明本发明。需要说明的是,在不冲突的情况下,本申请中的实施例及实施例中的特征可以相互组合。The invention will be described in detail below with reference to the drawings in conjunction with the embodiments. It should be noted that the embodiments in the present application and the features in the embodiments may be combined with each other without conflict.
需要说明的是,本发明的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别类似的对象,而不必用于描述特定的顺序或先后次序。It is to be understood that the terms "first", "second" and the like in the specification and claims of the present invention are used to distinguish similar objects, and are not necessarily used to describe a particular order or order.
研究发现在5G系统向4G系统切换过程中,AMF是和会话无关的网元,其没有会话相关数据。而MME必须根据切换请求中收到的会话相关参数(如bearer信息),在无线测(即eNB侧)预留资源。故在本发明实施例中,若用户设备从5G系统向4G系统切换时,则AMF会将预先保存的UE的目标承载信息发送至移动管理节点功能MME,如此MME接收到目标承载信息之后就可以为用户设备预留资源,从而提升避免由于UE无法获得资源或迟迟得不到4G系统的资源导致的切换延时大及切换后的数据传输时延大的问题。以下结合具体实施例进行进一步的解释和说明,但是本申请的保护范围应以权利要求的记载为准,并不限于以下实施例。本申请实施例一所提供的方法实施例可以在移动终端、计算机终端或者类似的运算装置中执行。以运行在计算机终端上为例,如图4所示,计算机终端可以包括一个或多个(图中仅示出一个)处理器401(处理器401可以包括但不限于微处理器MCU或可编程逻辑器件FPGA等的处理装置)、用于存储数据的存储器403、以及用于通信功能的传输装置405。本领域普通技术人员可以理解,图4所示的结构仅为示意,其并不对上述电子装置的结构造成限定。The research found that in the process of 5G system switching to 4G system, AMF is a network element unrelated to the session, and it has no session related data. The MME must reserve resources in the wireless measurement (ie, the eNB side) according to the session related parameters (such as bearer information) received in the handover request. Therefore, in the embodiment of the present invention, if the user equipment switches from the 5G system to the 4G system, the AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, so that the MME can receive the target bearer information. The resource is reserved for the user equipment, thereby improving the problem that the handover delay is large due to the inability of the UE to obtain resources or the resources of the 4G system are delayed, and the data transmission delay after the handover is large. The following further explanation and illustrations are made in conjunction with the specific embodiments, but the scope of the present application is defined by the claims, and is not limited to the following examples. The method embodiment provided in Embodiment 1 of the present application can be executed in a mobile terminal, a computer terminal or the like. For example, running on a computer terminal, as shown in FIG. 4, the computer terminal may include one or more (only one shown) processor 401 (the processor 401 may include, but is not limited to, a microprocessor MCU or programmable A processing device such as a logic device FPGA, a memory 403 for storing data, and a transmission device 405 for communication functions. It will be understood by those skilled in the art that the structure shown in FIG. 4 is merely illustrative and does not limit the structure of the above electronic device.
存储器403可配置为存储应用软件的软件程序以及模块,如本发明实施例中的设备的控制方法对应的程序指令/模块,处理器401通过运行存储在存储器403内的软件程序以及模块,从而执行各种功能应用以及数据处理,即实现上述的方法。存储器可包括高速随机存储器,还可包括非易失性存储器,如一个或者多个磁性存储装置、闪存、或者其他非易失性固态存储器。在一些实例中,存储器可进一步包括相对于处理器远程设置的存储器,这些远程存储器可以通过网络连接至计算机终端。上述网络的实例包括但不限于互联网、企业内部网、局域网、移动通信网及其组合。The memory 403 can be configured as a software program and a module for storing application software, such as program instructions/modules corresponding to the control method of the device in the embodiment of the present invention, and the processor 401 executes by executing a software program and a module stored in the memory 403. Various functional applications and data processing, that is, the above methods are implemented. The memory can include high speed random access memory and can also include non-volatile memory such as one or more magnetic storage devices, flash memory, or other non-volatile solid state memory. In some examples, the memory can further include memory remotely located relative to the processor, which can be connected to the computer terminal over a network. Examples of such networks include, but are not limited to, the Internet, intranets, local area networks, mobile communication networks, and combinations thereof.
传输装置用于经由一个网络接收或者发送数据。上述的网络具体实例可包括计算机终端的通信供应商提供的无线网络。在一个实例中,传输装置包括一个网络适配器(Network Interface Controller,NIC),其可通过基站与其他网络设备相连从而可与互联网进行通讯。The transmission device is for receiving or transmitting data via a network. The above-described network specific examples may include a wireless network provided by a communication provider of a computer terminal. In one example, the transmission device includes a Network Interface Controller (NIC) that can be connected to other network devices through the base station to communicate with the Internet.
需要说明的是,本申请的接入和移动性管理功能模块、移动管理节点功能模块可以为上述的计算机终端。It should be noted that the access and mobility management function module and the mobility management node function module of the present application may be the foregoing computer terminals.
根据本发明实施例,提供了一种跨系统的切换方法的方法实施例,需要说明的是,在附图的流程图示出的步骤可以在诸如一组计算机可执行指令的计算机系统中执行,并且,虽然在流程图中示出了逻辑顺序,但是在某些情况下,可以以不同于此处的顺序执行所示出或描述的步骤。In accordance with an embodiment of the present invention, a method embodiment of a method of switching across systems is provided, it being noted that the steps illustrated in the flowchart of the figures may be performed in a computer system such as a set of computer executable instructions. Also, although logical sequences are shown in the flowcharts, in some cases the steps shown or described may be performed in a different order than the ones described herein.
图5是根据本发明实施例的可选的跨系统的切换方法的流程图,如图5所示,该方法包括如下步骤:FIG. 5 is a flowchart of an optional cross-system switching method according to an embodiment of the present invention. As shown in FIG. 5, the method includes the following steps:
步骤S501,第一接入和移动性管理功能AMF获知用户设备UE发生跨系统切换,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统,第一AMF位于5G系统中。Step S501, the first access and mobility management function AMF learns that the user equipment UE cross-system handover, and the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system, first The AMF is located in a 5G system.
步骤S502,在UE从5G系统切换至4G系统的过程中,第一AMF将预先保存的UE的目标承载信息发送至移动管理节点功能MME,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。Step S502, in the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, and the MME located in the 4G system is used to receive the target bearer according to the received target. The information is that the UE reserves resources on the radio side.
通过上述实施例,接入和移动性管理功能第一AMF获知用户设备UE发生跨系统切换,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统,第一AMF位于5G系统中;在UE从5G系统切换至4G系统的过程中,第一AMF将预先保存的UE的目标承载信息发送至移动管理节点功能MME,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。从而解决了相关技术中在跨系统切换时由于AMF不能生成会话信息导致的无线侧不能为用户设备预留资源的技术问题,实现了在跨系统切换时在无线侧为用户设备预留资源的技术效果。Through the foregoing embodiment, the access and mobility management function first AMF learns that the user equipment UE cross-system handover, and the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system. The first AMF is located in the 5G system; in the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the pre-saved UE to the mobility management node function MME, and the MME located in the 4G system uses The received target bearer information is that the UE reserves resources on the radio side. Therefore, the technical problem that the wireless side cannot reserve resources for the user equipment caused by the AMF unable to generate session information during the cross-system handover in the related art is solved, and the technology for reserving resources for the user equipment on the wireless side during cross-system handover is realized. effect.
需要说明的是,在图1至图3中,AMF和MME之间的接口(如S1-C、S11、Gx、N2、N3、Nx、S5-C等)为这两个网元进行通讯的接口。It should be noted that, in FIG. 1 to FIG. 3, interfaces between the AMF and the MME (such as S1-C, S11, Gx, N2, N3, Nx, S5-C, etc.) communicate for the two network elements. interface.
上述的方法为运行于5G系统中的AMF的方法。The above method is a method of operating AMF in a 5G system.
在一个可选的实施例中,在第一AMF获知UE发生跨系统切换之前,第一AMF接收并保存5G系统中的会话控制功能SMF发送的缺省承载信息;目标承载信息至少包括缺省承载信息,缺省承载信息是在5G系统中为UE建立协议数据单元PDU会话的过程中,SMF生成的与PDU会话的缺省服务质量流Default Qos Flow对应的在4G系统中使用的承载信息。In an optional embodiment, before the first AMF learns that the UE cross-system handover, the first AMF receives and saves the default bearer information sent by the session control function SMF in the 5G system; the target bearer information includes at least the default bearer. The information, the default bearer information is the bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow generated by the SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system.
为了保证保存的缺省承载信息始终为最新的,在第一AMF接收并保存5G系统中的会话控制功能SMF发送的缺省承载信息之后,缺省服务质量流发生变化时,第一AMF接收SMF重新发送的缺省承载信息,其中,第一AMF当前接收到的缺省承载信息为在缺省服务质量流发生变化时,SMF生成的与变化后的缺省服务质量流对应的承载信息;第一AMF将保存的缺省承载信息替换为当前接收到的缺省承载信息。In order to ensure that the saved default bearer information is always up-to-date, after the first AMF receives and saves the default bearer information sent by the session control function SMF in the 5G system, when the default quality of service flow changes, the first AMF receives the SMF. The default bearer information that is retransmitted, where the default bearer information currently received by the first AMF is the bearer information corresponding to the changed default quality of service flow generated by the SMF when the default quality of service flow changes; An AMF replaces the saved default bearer information with the currently received default bearer information.
在另一个可选的实施例中,在第一AMF获知UE发生跨系统切换之前,第一AMF接收并保存5G系统中的SMF发送的专用承载信息;目标承载信息包括缺省承载信息和专用承载信息,专用承载信息是在5G系统中为UE建立专用服务质量流Dedicated Qos Flow时,SMF生成的与专用服务质量流对应的在4G系统中使用的承载信息。In another optional embodiment, before the first AMF learns that the UE cross-system handover occurs, the first AMF receives and saves the dedicated bearer information sent by the SMF in the 5G system; the target bearer information includes default bearer information and a dedicated bearer. The information, the dedicated bearer information is bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
在UE由第一AMF切换至5G系统中的第二AMF时,第一AMF将保存的UE的目标承载信息发送至第二AMF,其中,第二AMF用于保存接收到的UE的目标承载信息。When the UE is switched from the first AMF to the second AMF in the 5G system, the first AMF sends the saved target information of the UE to the second AMF, where the second AMF is used to save the target bearer information of the received UE. .
根据本发明实施例,还提供了一种跨系统的切换方法的方法实施例,该方法为运行于4G系统中MME的方法。该方法包括:According to an embodiment of the present invention, a method embodiment of a cross-system handover method is also provided, which is a method for running an MME in a 4G system. The method includes:
步骤S101,在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,移动管理节点功能MME接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,其中,第一AMF位于5G系统中,MME位于4G系统中;Step S101, in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, the mobility management node function MME receives the access and mobility management function of the UE sent by the first AMF. Target bearer information, wherein the first AMF is located in the 5G system, and the MME is located in the 4G system;
步骤S102,MME按照接收到的目标承载信息为UE在无线侧预留资源。Step S102: The MME reserves resources on the radio side for the UE according to the received target bearer information.
通过上述实施例,在用户设备UE从第五代移动通讯技术5G系统切换 至第四代移动通讯技术4G系统的过程中,移动管理节点功能MME接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,其中,第一AMF位于5G系统中,MME位于4G系统中,MME按照接收到的目标承载信息为UE在无线侧预留资源。从而解决了相关技术中在跨系统切换时由于AMF不能生成会话信息导致的无线侧不能为用户设备预留资源的技术问题,实现了在跨系统切换时在无线侧为用户设备预留资源的技术效果。Through the above embodiment, in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, the mobility management node function MME receives the access and mobility management function sent by the first AMF. Target bearer information of the UE, where the first AMF is located in the 5G system, and the MME is located in the 4G system, and the MME reserves resources for the UE on the radio side according to the received target bearer information. Therefore, the technical problem that the wireless side cannot reserve resources for the user equipment caused by the AMF unable to generate session information during the cross-system handover in the related art is solved, and the technology for reserving resources for the user equipment on the wireless side during cross-system handover is realized. effect.
可选的,在步骤S101中,MME接收第一AMF发送的UE的目标承载信息包括:MME接收第一AMF发送的缺省承载信息;其中,目标承载信息至少包括缺省承载信息,缺省承载信息是在5G系统中为UE建立协议数据单元PDU会话的过程中,会话控制功能SMF生成的与PDU会话的缺省服务质量流Default Qos Flow对应的在4G系统中使用的承载信息。Optionally, in step S101, the MME receives the target bearer information of the UE that is sent by the first AMF, where the MME receives the default bearer information sent by the first AMF, where the target bearer information includes at least default bearer information, and the default bearer. The information is bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow generated by the session control function SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system.
可选的,在步骤S101中,MME接收第一AMF发送的UE的目标承载信息还包括:MME接收第一AMF发送的专用承载信息;其中,目标承载信息包括缺省承载信息和专用承载信息,专用承载信息是在5G系统中为UE建立专用服务质量流Dedicated Qos Flow时,SMF生成的与专用服务质量流对应的在4G系统中使用的承载信息。Optionally, in step S101, the MME receiving the target bearer information of the UE that is sent by the first AMF further includes: the MME receiving the dedicated bearer information sent by the first AMF, where the target bearer information includes default bearer information and dedicated bearer information, The dedicated bearer information is bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
在本申请的实施例中,提供了一种跨系统的切换方法,UE在5G系统中建立PDU session(也即PDU会话)的过程中,网络侧SMF生成deafault Qos flow对应的Bearer信息(即承载信息)。SMF把该信息发给UE和AMF保存。In the embodiment of the present application, a cross-system handover method is provided. When a UE establishes a PDU session (that is, a PDU session) in a 5G system, the network side SMF generates Bearer information corresponding to the deafault Qos flow (ie, bearer information). information). The SMF sends this information to the UE and the AMF for saving.
当5G系统中为UE建立专有QoS flow时,网络生成Qos flow对应的Bearer信息,SMF把该信息发给UE和AMF保存。When a dedicated QoS flow is established for the UE in the 5G system, the network generates Bearer information corresponding to the QoS flow, and the SMF sends the information to the UE and the AMF for saving.
在5G向4G系统切换过程中,AMF把保存的bearer信息发送给MME。MME按照bearer信息,在无线侧预留资源。During the 5G to 4G system handover process, the AMF sends the saved bearer information to the MME. The MME reserves resources on the radio side according to the bearer information.
当UE在5G系统中,deafault Qos flow发生改变时,网络更新deafault Qos flow对应的Bearer信息,SMF并把更新后的信息发给UE和AMF保存。When the UE is in the 5G system, the deafault Qos flow changes, the network updates the Bearer information corresponding to the deafault Qos flow, and the SMF sends the updated information to the UE and the AMF for saving.
当UE在5G系统中内部发生AMF切换时,目的AMF(即切换后的AMF)从源AMF(切换前的AMF)获得保存的QoS flow对应的4G系统中的Bearer信息。When the UE internally performs AMF handover in the 5G system, the destination AMF (ie, the switched AMF) obtains Bearer information in the 4G system corresponding to the saved QoS flow from the source AMF (AMF before handover).
在一些实施例中还提供一种跨系统的切换方法,包括:In some embodiments, a cross-system switching method is also provided, including:
用户设备UE在第五代移动通讯技术5G系统中,接收与缺省服务质量流Default Qos Flow对应的目标承载信息,其中,所述目标承载信息为:所述UE在从5G系统切换到第四代移动通讯技术4G系统后使用的承载信息。例如,如图6、图7、图8及图9任意一个所示,AMF通过RRC配置请求携带所述目标承载信息下发给所述UE,则所述UE可以从对应的AMF接收到所述目标承载信息,从而开始执行所述5G系统到4G系统的切换等。The user equipment UE receives the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is switched from the 5G system to the fourth Bearer information used after the mobile communication technology 4G system. For example, as shown in any one of FIG. 6, FIG. 7, FIG. 8 and FIG. 9, the AMF sends the target bearer information to the UE by using an RRC configuration request, and the UE may receive the information from the corresponding AMF. The target carries information, thereby starting to perform switching of the 5G system to the 4G system, and the like.
可选地,所述目标承载信息,是所述第一AMF从会话管理功能SMF接收的。该目标承载信息可由SMF生成的。可选地,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话时,所述SMF生成的与所述缺省服务质量流对应的在所述4G系统中缺省承载的承载信息;所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中专用承载的承载信息。Optionally, the target bearer information is that the first AMF is received from the session management function SMF. The target bearer information can be generated by the SMF. Optionally, the default bearer information is the same as the default quality of service flow generated by the SMF in the 4G system when the protocol data unit PDU session is established for the UE in the 5G system. The bearer information of the default bearer; the dedicated bearer information is when the dedicated service quality stream (Dedicated Qos Flow) is established for the UE in the 5G system, and the SMF generates the corresponding service quality flow corresponding to the dedicated Bearer information of dedicated bearers in the 4G system.
本实施例还提供一种跨系统的切换装置,可应用于UE中,包括:The embodiment further provides a cross-system switching device, which can be applied to the UE, and includes:
接收单元,配置为用户设备UE在第五代移动通讯技术5G系统中,接收与缺省服务质量流Default Qos Flow对应的目标承载信息,其中,所述目标承载信息为:所述UE在从5G系统切换到第四代移动通讯技术4G系统后使用的承载信息。The receiving unit is configured to receive the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is in the slave 5G The bearer information used after the system switches to the 4G mobile communication technology 4G system.
该接收单元,可以配置为UE从5G系统切换到4G系统过程中,从第一AMF接收所述目标承载信息。在另一些实施例中,所述切换装置还可包括:存储单元,所述存储单元可用于存储所述目标承载信息。The receiving unit may be configured to receive the target bearer information from the first AMF during handover of the UE from the 5G system to the 4G system. In still other embodiments, the switching device may further include: a storage unit, where the storage unit is configured to store the target bearer information.
可选地,所述目标承载信息,是所述第一AMF从会话管理功能SMF接收的。该目标承载信息可由SMF生成的。可选地,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话时,所述SMF生成的与所述缺省服务质量流对应的在所述4G系统中缺省承载的承载信息;所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中专用承载的承载信息。Optionally, the target bearer information is that the first AMF is received from the session management function SMF. The target bearer information can be generated by the SMF. Optionally, the default bearer information is the same as the default quality of service flow generated by the SMF in the 4G system when the protocol data unit PDU session is established for the UE in the 5G system. The bearer information of the default bearer; the dedicated bearer information is when the dedicated service quality stream (Dedicated Qos Flow) is established for the UE in the 5G system, and the SMF generates the corresponding service quality flow corresponding to the dedicated Bearer information of dedicated bearers in the 4G system.
下面结合图6至图12详述本申请的实施例。Embodiments of the present application are described in detail below with reference to FIGS. 6 through 12.
图6是本发明实施例中PDU会话建立的一种实施方式。FIG. 6 is an implementation manner of establishing a PDU session in an embodiment of the present invention.
步骤S601,终端确定发起新的PDU会话,于是发起PDU会话建立请求,UE向AMF发送的移动性NAS消息,其中包含UE向SMF发送的会话NAS消息信元。会话NAS消息信元中带有新请求会话的PDU会话类型、选择的SSC模式等,以及支持5G和4G IWK的指示。Step S601: The terminal determines to initiate a new PDU session, and then initiates a PDU session establishment request, and the mobility NAS message sent by the UE to the AMF includes the session NAS message cell sent by the UE to the SMF. The session NAS message cell has a PDU session type with a new request session, a selected SSC mode, etc., and an indication to support 5G and 4G IWK.
步骤S602,NG RAN将PDU会话建立请求发送至AMF。Step S602, the NG RAN sends a PDU session establishment request to the AMF.
步骤S603,AMF收到并解析移动性NAS消息,根据其中信息选择合适的SMF(也就是本申请中的SMF/PGW-C),并保存PDU会话标识和选择的SMF之间的对应关系。AMF将会话NAS消息、数据网名字以及用户标识、PDU会话标识一起转发给选择的SMF(也即发送会话建立请求发送至SMF)。Step S603, the AMF receives and parses the mobility NAS message, selects an appropriate SMF according to the information therein (that is, SMF/PGW-C in the present application), and saves the correspondence between the PDU session identifier and the selected SMF. The AMF forwards the session NAS message, the data network name, and the user identity, PDU session ID to the selected SMF (ie, the send session establishment request is sent to the SMF).
步骤S604,SMF从SDM获得用户的签约数据。Step S604, the SMF obtains the subscription data of the user from the SDM.
步骤S605,SMF检查用户签约,判断是否允许该PDU会话请求,并确定该PDU会话预授权的QoS信息,其中包含了UE在4G接入时的缺省承载的信息(包含QoS)。可选的SMF还可能和PCF协商以确定该PDU会话所需要的default QoS信息,以及4G接入时的缺省承载的信息(包含QoS)。Step S605, the SMF checks the user subscription, determines whether the PDU session request is allowed, and determines the QoS information of the PDU session pre-authorization, which includes information (including QoS) of the default bearer of the UE when the 4G access is performed. The optional SMF may also negotiate with the PCF to determine the default QoS information required for the PDU session, as well as the default bearer information (including QoS) for 4G access.
步骤S606,SMF根据会话信息,选择合适的用户面功能UPF,并向选择的UPF发送N4会话建立请求,消息请求中带有请求的QoS等信息,其中至少包括QoS流标签以及对应的上下行流模板。UPF建立N4会话相关上下文,保存QoS信息,UPF分配该会话的N3隧道上行隧道标识,并向SMF返回N4会话建立响应,其中带有UPF分配的N3隧道上行隧道标识。Step S606: The SMF selects an appropriate user plane function UPF according to the session information, and sends an N4 session establishment request to the selected UPF. The message request includes the requested QoS and the like, and at least includes the QoS flow label and the corresponding uplink and downlink flows. template. The UPF establishes an N4 session-related context, and stores the QoS information. The UPF allocates the N3 tunnel uplink tunnel identifier of the session, and returns an N4 session establishment response to the SMF, where the UP3 allocates the N3 tunnel uplink tunnel identifier.
步骤S607,SMF获取UPF分配的隧道标识,并通过AMF向基站请求建立该会话的无线资源。SMF向AMF发送的消息中带有SM信元,信元中包括PDU会话标识、该会话请求的QoS信息和UPF为该会话分配的N3隧道上行隧道标识。此外,SMF把default QoS flow的信息和UE在4G接入时的缺省承载的信息也带给AMF,AMF保存其中的4G接入时的缺省承载的信息(包含QoS)。Step S607, the SMF acquires the tunnel identifier allocated by the UPF, and requests the base station to establish the radio resource of the session through the AMF. The SMF sends a message to the AMF with the SM cell. The cell includes the PDU session identifier, the QoS information of the session request, and the N3 tunnel uplink tunnel identifier assigned by the UPF to the session. In addition, the SMF brings the information of the default QoS flow and the information of the default bearer of the UE during 4G access to the AMF, and the AMF stores the information (including QoS) of the default bearer when the 4G access is performed.
步骤S608,AMF向基站发送N2-AP无线资源建立请求消息。其中包含 AMF收到的default QoS flow的信息和UE在4G接入时的缺省承载的信息。Step S608, the AMF sends an N2-AP radio resource setup request message to the base station. It contains the information of the default QoS flow received by the AMF and the default bearer information of the UE when it accesses the 4G.
步骤S609,基站根据收到QoS信息分配无线资源,并和终端交互,建立该会话的无线专用承载。在基站发送给UE的无线资源控制(Radio Resource Control,RRC)配置请求消息中,携带了从AMF收到的default QoS flow的信息和UE在4G接入时的缺省承载的信息。基站分配N3隧道下行隧道标识。Step S609, the base station allocates a radio resource according to the received QoS information, and interacts with the terminal to establish a wireless dedicated bearer of the session. The radio resource control (RRC) configuration request message sent by the base station to the UE carries the information of the default QoS flow received from the AMF and the information of the default bearer of the UE when the 4G accesses. The base station allocates an N3 tunnel downlink tunnel identifier.
步骤S610,终端进行RRC配置响应。Step S610, the terminal performs an RRC configuration response.
步骤S611,基站向AMF返回N2-AP无线资源建立响应消息,其中带有基站分配的N3隧道下行隧道标识,即如图6所示,NG RAM向AMF发送无线资源建立响应。Step S611, the base station returns an N2-AP radio resource setup response message to the AMF, where the N3 tunnel downlink tunnel identifier is allocated by the base station, that is, as shown in FIG. 6, the NG RAM sends a radio resource setup response to the AMF.
步骤S612,AMF向SMF返回无线资源建立响应消息,其中带有基站分配的N3隧道下行隧道标识,即如图6所示,AMF向SMF发送无线资源建立响应。Step S612, the AMF returns a radio resource setup response message to the SMF, where the N3 tunnel downlink tunnel identifier is allocated by the base station, that is, as shown in FIG. 6, the AMF sends a radio resource setup response to the SMF.
步骤S613,SMF向UPF发送N4会话更新请求,将基站分配的N3隧道下行隧道标识发送给用户面功能(User Plane Function,UPF)。In step S613, the SMF sends an N4 session update request to the UPF, and sends the N3 tunnel downlink tunnel identifier assigned by the base station to the User Plane Function (UPF).
步骤S614,可选的,AMF也可以把default QoS flow的信息和UE在4G接入时的缺省承载的信息通过NAS消息发给UE。Step S614, optionally, the AMF may also send the information of the default QoS flow and the information of the default bearer of the UE when the 4G access is sent to the UE by using the NAS message.
上述的步骤S612和步骤S614可以是并行的。The above steps S612 and S614 may be in parallel.
步骤S615,SMF向AMF返回PDU会话建立响应,带有该会话的QoS信息,至少包括预授权的QoS流标识以及对应的上行流模板。可选的,也可以包含default QoS flow的信息和UE在4G接入时的缺省承载的信息,AMF把4G接入时的缺省承载的信息作为透明数据保存。Step S615, the SMF returns a PDU session establishment response to the AMF, and the QoS information of the session includes at least a pre-authorized QoS flow identifier and a corresponding upstream template. Optionally, the information about the default QoS flow and the information about the default bearer of the UE when the 4G is accessed may be included, and the AMF stores the information of the default bearer when the 4G access is used as the transparent data.
步骤S616,AMF向UE转发PDU会话建立响应。终端保存收到的default Qos flow的信息以及UE在4G接入时的缺省承载的信息。Step S616, the AMF forwards the PDU session establishment response to the UE. The terminal saves the information of the received default Qos flow and the default bearer information of the UE when accessing the 4G.
步骤S617,PDU会话建立完成,UE通过该PDU会话请求网络分配IP地址,通过上述步骤建立了新的PDU会话,终端可以通过该PDU会话发送和接受上下行数据。In step S617, the PDU session is established, and the UE requests the network to allocate an IP address through the PDU session, and a new PDU session is established through the foregoing steps, and the terminal can send and receive uplink and downlink data through the PDU session.
图7是本发明实施例中提供的在本地路由(Home Routed)场景下的PDU会话建立的一种实施方式的一种。FIG. 7 is a schematic diagram of an embodiment of establishing a PDU session in a Home Routed scenario according to an embodiment of the present invention.
步骤S701,终端确定发起新的PDU会话,于是发起PDU会话建立请求,UE向AMF发送的移动性NAS消息,其中包含UE向SMF发送的会话NAS消息信元。会话NAS消息信元中带有新请求会话的PDU会话类型、选择的SSC模式等,以及支持5G和4G IWK的指示。Step S701: The terminal determines to initiate a new PDU session, and then initiates a PDU session establishment request, and the mobility NAS message sent by the UE to the AMF includes the session NAS message cell sent by the UE to the SMF. The session NAS message cell has a PDU session type with a new request session, a selected SSC mode, etc., and an indication to support 5G and 4G IWK.
步骤S702,AMF收到并解析移动性NAS消息,根据其中信息选择合适的拜访网络V-SMF,并保存PDU会话标识和选择的V-SMF之间的对应关系。AMF将会话NAS消息、数据网名字以及用户标识、PDU会话标识一起转发给选择的V-SMF,即发送PDU会话建立请求。Step S702, the AMF receives and parses the mobility NAS message, selects an appropriate visited network V-SMF according to the information therein, and saves the correspondence between the PDU session identifier and the selected V-SMF. The AMF forwards the session NAS message, the data network name, and the user ID and the PDU session identifier to the selected V-SMF, that is, sends a PDU session establishment request.
步骤S703,建立N4会话,V-SMF根据会话信息,选择合适的用户面功能V-UPF,并向选择的V-UPF发送N4会话建立请求。V-UPF分配该会话的N3隧道上行隧道标识,以及N9隧道下行标识,并返回给V-SMF。Step S703, an N4 session is established, and the V-SMF selects an appropriate user plane function V-UPF according to the session information, and sends an N4 session establishment request to the selected V-UPF. The V-UPF allocates the N3 tunnel uplink tunnel identifier of the session, and the N9 tunnel downlink identifier, and returns it to the V-SMF.
步骤S704,V-SMF向用户的归属网络转发会话NAS消息(包含N9隧道下行标识)。用户归属网络选择合适的H-SMF(也就是本申请中的SMF/PGW-C)。H-SMF从SDM获得用户的签约数据。(简化期间,图中没有显示),即发送PDU会话建立请求。Step S704, the V-SMF forwards the session NAS message (including the N9 tunnel downlink identifier) to the user's home network. The user home network selects the appropriate H-SMF (also known as SMF/PGW-C in this application). The H-SMF obtains the user's subscription data from the SDM. (Simplified period, not shown in the figure), that is, a PDU session establishment request is sent.
步骤S705,H-SMF检查用户签约,判断是否允许该PDU会话请求,并确定该PDU会话预授权的QoS信息,其中包含了UE在4G接入时的缺省承载的信息(包含QoS)。可选的SMF还可能和PCF协商以确定该PDU会话所需要的default QoS信息,以及4G接入时的缺省承载的信息(包含QoS)。Step S705: The H-SMF checks the user subscription, determines whether the PDU session request is allowed, and determines the QoS information of the pre-authorization of the PDU session, where the information (including QoS) of the default bearer of the UE when the 4G access is included. The optional SMF may also negotiate with the PCF to determine the default QoS information required for the PDU session, as well as the default bearer information (including QoS) for 4G access.
步骤S706,H-SMF根据会话信息,选择合适的用户面功能H-UPF,并向选择的H-UPF发送N4会话建立请求,消息请求中带有请求的QoS等信息,其中至少包括QoS流标签以及对应的上下行流模板,以及N9隧道下行标识。H-UPF建立N4会话相关上下文,保存QoS信息,UPF分配该会话的N9隧道上行隧道标识,并向SMF返回N4会话建立响应,其中带有H-UPF分配的N9隧道上行隧道标识。Step S706: The H-SMF selects an appropriate user plane function H-UPF according to the session information, and sends an N4 session establishment request to the selected H-UPF, where the message request carries information such as requested QoS, where at least the QoS flow label is included. And the corresponding uplink and downlink flow template, and the N9 tunnel downlink identifier. The H-UPF establishes an N4 session-related context, and stores the QoS information. The UPF allocates the N9 tunnel uplink tunnel identifier of the session, and returns an N4 session setup response to the SMF, where the N9 tunnel uplink tunnel identifier is allocated by the H-UPF.
步骤S707,无线资源请求建立。H-SMF获取UPF分配的隧道标识,并通过V-SMF、AMF向基站请求建立该会话的无线资源。该消息发给V-SMF, 包含SM信元,信元中包括PDU会话标识、该会话请求的QoS信息和UPF为该会话分配的N9隧道上行隧道标识,V-SMF把其中的N9隧道上行标识替换为N3隧道上行标识,然后把该信息转发给AMF。其中,QoS信息还包含了UE在4G接入时的缺省承载的信息。Step S707, the radio resource request is established. The H-SMF obtains the tunnel identifier assigned by the UPF, and requests the base station to establish the radio resource of the session through the V-SMF and the AMF. The message is sent to the V-SMF, and includes the SM cell. The cell includes the PDU session identifier, the QoS information of the session request, and the N9 tunnel uplink tunnel identifier allocated by the UPF for the session, and the V-SMF identifies the N9 tunnel uplink identifier. Replace with the N3 tunnel upstream identifier and forward the information to AMF. The QoS information also includes information about the default bearer of the UE when the 4G is accessed.
步骤S708,V-SMF将该消息准发给AMF,AMF保存其中的4G接入时的缺省承载的信息(包含QoS),即发送无线资源请求建立消息。Step S708: The V-SMF sends the message to the AMF, and the AMF saves the information (including QoS) of the default bearer when the 4G access is performed, that is, sends a radio resource request setup message.
步骤S709,AMF向基站发送N2-AP无线资源建立请求消息。其中包含AMF收到的default QoS flow的信息和UE在4G接入时的缺省承载的信息。Step S709, the AMF sends an N2-AP radio resource setup request message to the base station. It contains the information of the default QoS flow received by the AMF and the default bearer information of the UE when it accesses the 4G.
步骤S710,基站根据收到QoS信息分配无线资源,并和终端交互,建立该会话的无线专用承载。可选的,在基站发送给UE的RRC配置请求消息中,携带了从AMF收到的default QoS flow的信息和UE在4G接入时的缺省承载的信息。基站分配N3隧道下行隧道标识。Step S710: The base station allocates a radio resource according to the received QoS information, and interacts with the terminal to establish a wireless dedicated bearer of the session. Optionally, the RRC configuration request message sent by the base station to the UE carries information about the default QoS flow received from the AMF and information about the default bearer of the UE when the 4G is accessed. The base station allocates an N3 tunnel downlink tunnel identifier.
步骤S711,返回RRC配置响应消息。Step S711, returning an RRC configuration response message.
步骤S712,基站向AMF返回N2-AP无线资源建立响应消息,其中带有基站分配的N3隧道下行隧道标识。Step S712, the base station returns an N2-AP radio resource setup response message to the AMF, where the N3 tunnel downlink tunnel identifier allocated by the base station is carried.
步骤S713,AMF向V-SMF返回无线资源建立响应消息,其中带有基站分配的N3隧道下行隧道标识。Step S713, the AMF returns a radio resource setup response message to the V-SMF, where the N3 tunnel downlink tunnel identifier allocated by the base station is carried.
步骤S714,V-SMF向UPF发送N4会话更新请求,将基站分配的N3隧道下行隧道标识,H-UPF分配的N9隧道上行标识发送给V-UPF。Step S714: The V-SMF sends an N4 session update request to the UPF, and sends the N3 tunnel downlink tunnel identifier allocated by the base station and the N9 tunnel uplink identifier allocated by the H-UPF to the V-UPF.
步骤S715,V-SMF转发无线资源建立响应给H-SMF。Step S715, the V-SMF forwards the radio resource setup response to the H-SMF.
步骤S716,可选的,AMF也可以把default QoS flow的信息和UE在4G接入时的缺省承载的信息通过NAS消息发给UE。Step S716, optionally, the AMF may also send the information of the default QoS flow and the information of the default bearer of the UE when the 4G access is sent to the UE by using the NAS message.
上述的步骤S716和步骤S713可以是并行的。The above steps S716 and S713 may be in parallel.
步骤S717,H-SMF向AMF返回PDU会话建立响应,带有该会话的QoS信息,至少包括预授权的QoS流标识以及对应的上行流模板。可选的,也可以包含default QoS flow的信息和UE在4G接入时的缺省承载的信息,AMF把4G接入时的缺省承载的信息作为透明数据保存。该消息通过V-SMF转发给AMF。Step S717: The H-SMF returns a PDU session establishment response to the AMF, and the QoS information of the session includes at least a pre-authorized QoS flow identifier and a corresponding upstream template. Optionally, the information about the default QoS flow and the information about the default bearer of the UE when the 4G is accessed may be included, and the AMF stores the information of the default bearer when the 4G access is used as the transparent data. This message is forwarded to the AMF via the V-SMF.
步骤S718,AMF向UE转发PDU会话建立响应。终端保存收到的预授权QoS信息以及UE在4G接入时的缺省承载的信息。Step S718, the AMF forwards the PDU session establishment response to the UE. The terminal saves the received pre-authorization QoS information and the information of the default bearer of the UE when the 4G accesses.
步骤S719,UE向AMF告知PUD会话建立完成。Step S719, the UE informs the AMF that the PUD session establishment is completed.
步骤S720,AMF向H-SMF告知PUD会话建立完成。UE通过该PDU会话请求网络分配IP地址,通过上述步骤建立了新的PDU会话,终端可以通过该PDU会话发送和接受上下行数据。In step S720, the AMF informs the H-SMF that the PUD session establishment is completed. The UE requests the network to allocate an IP address through the PDU session, and a new PDU session is established through the foregoing steps, and the terminal can send and receive uplink and downlink data through the PDU session.
图8是本发明实施例中QoS flow建立和更新的一种实施方式的一种。FIG. 8 is a diagram of an embodiment of QoS flow establishment and update in an embodiment of the present invention.
步骤S801,应用功能(Application Function,AF)请求向PCF/PCRF请求会话的资源。Step S801, an Application Function (AF) request requests a resource of a session from the PCF/PCRF.
步骤S802,PCF/PCRF根据策略,向SMF发送UE的QoS flow的信息,如增加新的QoS flow,或者更新现有的QoS flow。其中还包含了该QoS flow映射到4G接入时的承载信息。Step S802, the PCF/PCRF sends the information of the QoS flow of the UE to the SMF according to the policy, such as adding a new QoS flow, or updating an existing QoS flow. It also includes bearer information when the QoS flow is mapped to 4G access.
步骤S803,SMF/PGW-C更新UPF/PGW-U的QoS flow信息,如增加新的QoS flow,或者更新现有的QoS flow,其中,PGW-C更新PGW-U上的承载信息。Step S803, the SMF/PGW-C updates the QoS flow information of the UPF/PGW-U, such as adding a new QoS flow, or updating the existing QoS flow, wherein the PGW-C updates the bearer information on the PGW-U.
步骤S804,SMF通过AMF向基站请求建立该会话的无线资源。SMF向AMF发送的消息中带有SM信元,信元中包括PDU会话标识、该会话请求的QoS flow信息,和UE在4G接入时的该QoS flow对应的承载信息也带给AMF,AMF保存其中的4G接入时的对应的承载信息的信息。Step S804, the SMF requests the base station to establish a radio resource of the session through the AMF. The SMF sends a message to the AMF with the SM cell. The cell includes the PDU session identifier, the QoS flow information of the session request, and the bearer information corresponding to the QoS flow of the UE when the 4G access is also brought to the AMF, AMF. The information of the corresponding bearer information when the 4G access is saved.
步骤S805,AMF向基站发送N2-AP无线资源建立请求消息。其中包含AMF收到的QoS flow的信息,以及UE在4G接入时的对应的承载信息。Step S805, the AMF sends an N2-AP radio resource setup request message to the base station. The information about the QoS flow received by the AMF and the corresponding bearer information when the UE accesses the 4G are included.
步骤S806,基站根据收到QoS信息分配无线资源,并和终端交互,建立或更新该会话的无线专用承载。基站发送给UE的RRC消息中,携带了从AMF收到的QoS flow的信息和UE在4G接入时对应的承载信息。Step S806, the base station allocates a radio resource according to the received QoS information, and interacts with the terminal to establish or update a wireless dedicated bearer of the session. The RRC message sent by the base station to the UE carries the information of the QoS flow received from the AMF and the bearer information corresponding to the UE when the 4G accesses.
步骤S807,返回RRC配置响应。Step S807, returning an RRC configuration response.
步骤S808,基站向AMF返回N2-AP无线资源建立响应消息。Step S808, the base station returns an N2-AP radio resource setup response message to the AMF.
步骤S809,AMF向SMF返回无线资源建立响应消息。Step S809, the AMF returns a radio resource setup response message to the SMF.
步骤S810,可选的,AMF也可以把QoS flow的信息和UE在4G接入时对应的承载信息通过NAS消息发给UE。Step S810, optionally, the AMF may also send the information of the QoS flow and the bearer information corresponding to the UE during the 4G access to the UE by using the NAS message.
上述的步骤S809和步骤S810可以是并行的。The above steps S809 and S810 may be in parallel.
图9是本发明实施例中default QoS flow信息发生改变时的一种实施方式。FIG. 9 is an embodiment of the default QoS flow information in the embodiment of the present invention.
步骤S901,由于各种原因,default Qos flow的信息发生了改变,如PCF/PCRF通知SMF。In step S901, the information of the default Qos flow is changed for various reasons, such as the PCF/PCRF notifying the SMF.
步骤S902,SMF/PGW-C更新UPF/PGW-U的default QoS flow信息。其中,也可能需要PGW-C更新PGW-U上的缺省承载信息。In step S902, the SMF/PGW-C updates the default QoS flow information of the UPF/PGW-U. Among them, the PGW-C may also need to update the default bearer information on the PGW-U.
步骤S903,SMF通过AMF向基站请求更新default QoS flow的无线资源。SMF向AMF发送的消息中带有SM信元,信元中包括PDU会话标识、该会话请求的default QoS flow信息,和UE在4G接入时的缺省承载信息也带给AMF,AMF更新其以前保存其中的4G接入时的对应缺省承载信息。Step S903, the SMF requests the base station to update the radio resource of the default QoS flow through the AMF. The message sent by the SMF to the AMF carries the SM cell, and the cell includes the PDU session identifier, the default QoS flow information of the session request, and the default bearer information of the UE when the 4G access is also brought to the AMF, and the AMF updates its Previously, the corresponding default bearer information when 4G access is saved.
步骤S904,AMF向基站发送N2-AP无线资源更新请求消息。其中包含AMF收到的default QoS flow的信息,以及UE在4G接入时的缺省承载信息。Step S904, the AMF sends an N2-AP radio resource update request message to the base station. It contains the information of the default QoS flow received by the AMF and the default bearer information of the UE when it accesses the 4G.
步骤S905,基站根据收到QoS信息更新无线资源,并和终端交互,更新该会话的无线专用承载。基站发送给UE的RRC消息中,携带了从AMF收到的default QoS flow的信息和UE在4G接入时对应的缺省承载信息,例如,基站根据QoS信息发送RRC配置请求。Step S905, the base station updates the radio resource according to the received QoS information, and interacts with the terminal to update the wireless dedicated bearer of the session. The RRC message sent by the base station to the UE carries the information of the default QoS flow received from the AMF and the default bearer information corresponding to the UE when the 4G accesses. For example, the base station sends an RRC configuration request according to the QoS information.
步骤S906,返回RRC配置响应。Step S906, returning an RRC configuration response.
步骤S907,基站向AMF返回N2-AP无线资源更新响应消息。Step S907, the base station returns an N2-AP radio resource update response message to the AMF.
步骤S908,AMF向SMF返回无线资源更新响应消息。Step S908, the AMF returns a radio resource update response message to the SMF.
步骤S909,可选的,AMF也可以把default QoS flow的信息和UE在4G接入时的缺省承载信息通过NAS消息发给UE。Step S909, optionally, the AMF may also send the information of the default QoS flow and the default bearer information of the UE during 4G access to the UE by using the NAS message.
上述的步骤S908和步骤S909可以是并行的。The above steps S908 and S909 may be in parallel.
图10是UE在空闲(idle)态下移动,发生AMF改变的一种实施方式。FIG. 10 is an embodiment in which the UE moves in an idle state and an AMF change occurs.
步骤S1001,UE向NG基站发送NAS消息,如跟踪区更新(Tracking Area Update,TAU)。Step S1001: The UE sends a NAS message, such as a Tracking Area Update (TAU), to the NG base station.
步骤S1002,基站选择了一个新的AMF(也就是tAMF),并将NAS消息转发给tAMF。In step S1002, the base station selects a new AMF (ie, tAMF) and forwards the NAS message to the tAMF.
步骤S1003,tAMF向sAMF请求用户的上下文。In step S1003, the tAMF requests the context of the user from the sAMF.
步骤S1004,sAMF提供上下文响应,sAMF将UE的安全上下文,会话上下文(每个PDU会话信息,包括SMF地址,PDU会话ID等)发送给tAMF,其中包括了每个PDU会话对应的在4G接入时的缺省承载信息。Step S1004, the sAMF provides a context response, and the sAMF sends the security context of the UE, the session context (each PDU session information, including the SMF address, the PDU session ID, and the like) to the tAMF, where the 4G access corresponding to each PDU session is included. Default bearer information.
步骤S1005,tAMF根据收到的上下文,基于每PDU会话,建立该会话中,和对应的SMF的N11接口。Step S1005: The tAMF establishes, according to the received context, an N11 interface in the session and the corresponding SMF based on each PDU session.
步骤S1006,SMF返回建立接口响应。In step S1006, the SMF returns to establish an interface response.
随后的步骤和现有的空闲(idle)态移动后TAU流程一样,在此不再赘述。The subsequent steps are the same as the existing idle state after the TAU process, and will not be described here.
图11是UE在连接(connected)态下移动,发生AMF改变的的一种实施方式。Figure 11 is an embodiment of the UE moving in a connected state, with AMF changes occurring.
步骤S1101,UE在connect态下移动,5G基站确定需要发起切换。NG RAN向sAMF发送切换请求。In step S1101, the UE moves in the connect state, and the 5G base station determines that the handover needs to be initiated. The NG RAN sends a handover request to the sAMF.
步骤S1102,sAMF发现目标5G基站不在范围,sAMF选择新的AMF(也就是tSMF)。向tSMF发送切换请求。其中包含了安全上下文,会话上下文(对于每个PDU session,包含了SMF地址,PDU会话ID等)发送给tAMF,其中包括了每个PDU会话对应的在4G接入时的缺省承载信息,以及可选的,普通QoS flow对应的专用承载信息。In step S1102, the sAMF finds that the target 5G base station is out of range, and the sAMF selects a new AMF (that is, tSMF). A handover request is sent to the tSMF. The security context is included, and the session context (including the SMF address, PDU session ID, etc. for each PDU session) is sent to the tAMF, which includes the default bearer information for each PDU session at the time of 4G access, and Optionally, the dedicated bearer information corresponding to the normal QoS flow.
步骤S1103,tAMF根据收到的上下文,基于每PDU会话,建立该会话中,和对应的SMF的N11接口。Step S1103: The tAMF establishes an N11 interface in the session and the corresponding SMF based on the received context based on the received PDU session.
步骤S1104,SMF返回建立响应。In step S1104, the SMF returns a setup response.
步骤S1105,tAMF请求目标侧基站预留资源。In step S1105, the tAMF requests the target side base station to reserve resources.
步骤S1106,tAMF向sAMF返回切换请求响应。In step S1106, the tAMF returns a handover request response to the sAMF.
随后的步骤和现有的connect态切换流程一样,在此不再赘述。The subsequent steps are the same as the existing connect state switching process, and will not be described here.
图12是本发明实施例中5G向4G切换的流程示意图。FIG. 12 is a schematic flowchart of switching from 5G to 4G in the embodiment of the present invention.
UE发起PDU会话建立过程,参考前述实施例,UE附着到了NG system,并建立了PDU session。The UE initiates a PDU session establishment process. Referring to the foregoing embodiment, the UE attaches to the NG system and establishes a PDU session.
步骤S1201,NG基站(NR RAN)确定需要发起切换,NG RAN向AMF发送切换请求。In step S1201, the NG base station (NR RAN) determines that the handover needs to be initiated, and the NG RAN sends a handover request to the AMF.
步骤S1202,AMF判断是从5G切换到4G系统,向MME发送切换请求。其中对于每个PDU session,包含了SMF地址、APN,以及存储的UE在4G接入时,对应的承载信息(参见前述实施例),其中至少包含缺省承载信息,可选的,也可能包含专用承载信息。In step S1202, the AMF determines to switch from 5G to the 4G system, and sends a handover request to the MME. For each PDU session, the SMF address, the APN, and the corresponding bearer information of the stored UE when the 4G access is used (refer to the foregoing embodiment), where at least the default bearer information is included, optionally, may also include Dedicated bearer information.
步骤S1203,MME根据收到的会话信息,按照每会话选择合适的S-GW发送create session请求(会话生成请求)。Step S1203: The MME selects a suitable S-GW to send a create session request (session generation request) according to the received session information.
步骤S1204,发送切换准备请求,MME根据收到的会话信息,向E-UTRAN请求建立缺省承载资源。其中,每个会话都要建立对应的缺省承载资源。Step S1204: Send a handover preparation request, and the MME requests the E-UTRAN to establish a default bearer resource according to the received session information. Each session must establish a corresponding default bearer resource.
步骤S1205,E-UTRAN预留UE在无线侧接入时需要的无线资源,并返回切换准备请求响应消息,其中带有预留的无线资源信息。该消息还带有目的基站2为每个预留资源成功的PDN Connection分配的S1-U下行隧道标识。Step S1205: The E-UTRAN reserves the radio resources required for the UE to access the radio side, and returns a handover preparation request response message with reserved radio resource information. The message also carries the S1-U downlink tunnel identifier assigned by the destination base station 2 for each PDN Connection that is successfully reserved.
步骤S1206,MME向AMF返回切换请求响应,其中包含了目标基站的无线资源信息。Step S1206: The MME returns a handover request response to the AMF, where the radio resource information of the target base station is included.
步骤S1207,AMF向NG基站返回切换请求响应消息,带有目的基站(E-UTRAN基站)为这些PDU会话预留的无线资源信息。Step S1207, the AMF returns a handover request response message to the NG base station, with the radio resource information reserved by the destination base station (E-UTRAN base station) for these PDU sessions.
步骤S1208,NG基站向UE发送切换命令,带有目的基站预留的无线资源信息。Step S1208: The NG base station sends a handover command to the UE, with the radio resource information reserved by the destination base station.
步骤S1209,用户设备UE从4G基站接入。Step S1209: The user equipment UE accesses from the 4G base station.
步骤S1210,eNB向MME发送切换完成消息。In step S1210, the eNB sends a handover complete message to the MME.
步骤S1211至S1215,和现有的4G跨MME切换技术一样,在此仅仅简单描述一下。Steps S1211 to S1215 are the same as the existing 4G cross-MME switching technology, and are simply described here.
步骤S1211,MME向S-GW发送会话更新请求,其中携带了S1-U下行隧道标识。Step S1211: The MME sends a session update request to the S-GW, where the S1-U downlink tunnel identifier is carried.
步骤S1212,S-GW向PGW-C发送会话更新请求,其中还携带了S-GW的媒体信息。Step S1212: The S-GW sends a session update request to the PGW-C, where the media information of the S-GW is also carried.
步骤S1213,PGW-C和PGW-U交互,分配媒体面资源。In step S1213, PGW-C and PGW-U interact to allocate media plane resources.
步骤S1214,PGW-C向S-GW返回会话更新请求的应答,其中携带了PGW-U的媒体信息。Step S1214, the PGW-C returns a response to the session update request to the S-GW, where the media information of the PGW-U is carried.
步骤S1215,S-GW向MME返回会话更新的应答(也即会话更新响应);此时UE能在4G PDN connection的缺省承载上,发送/接收上下行数据。In step S1215, the S-GW returns a response to the session update (ie, a session update response) to the MME; at this time, the UE can send/receive uplink and downlink data on the default bearer of the 4G PDN connection.
步骤S1216,MME向AMF发送切换完成指示。In step S1216, the MME sends a handover completion indication to the AMF.
步骤S1217,AMF释放和NG基站的N2接口。之后P-GW发起其余专用承载的激活过程。In step S1217, the AMF releases the N2 interface of the NG base station. The P-GW then initiates the activation process for the remaining dedicated bearers.
此外,一种可选实现方式是,如果在步骤S1202,AMF发给MME的切换请求中,不仅包含了缺省承载信息,还包含了QoS flow对应的4G专用承载信息,则在步骤S1204中,MME不仅请求缺省承载资源,还请求了专用承载资源。此时,就不需要P-GW发起其余专用承载的激活过程。In addition, an optional implementation manner is: if the default bearer information is included in the handover request sent by the AMF to the MME in step S1202, and the 4G dedicated bearer information corresponding to the QoS flow is included, then in step S1204, The MME not only requests the default bearer resource, but also requests the dedicated bearer resource. At this time, the P-GW is not required to initiate the activation process of the remaining dedicated bearers.
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到根据上述实施例的方法可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件,但很多情况下前者是更佳的实施方式。基于这样的理解,本发明的技术方案本质上或者说对现有技术做出贡献的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质(如ROM/RAM、磁碟、光盘)中,包括若干指令用以使得一台终端设备(可以是 手机,计算机,服务器,或者网络设备等)执行本发明各个实施例所述的方法。Through the description of the above embodiments, those skilled in the art can clearly understand that the method according to the above embodiment can be implemented by means of software plus a necessary general hardware platform, and of course, by hardware, but in many cases, the former is A better implementation. Based on such understanding, the technical solution of the present invention, which is essential or contributes to the prior art, may be embodied in the form of a software product stored in a storage medium (such as ROM/RAM, disk, The optical disc includes a number of instructions for causing a terminal device (which may be a cell phone, a computer, a server, or a network device, etc.) to perform the methods described in various embodiments of the present invention.
本发明实施例中还提供了一种跨系统的切换装置。该装置用于实现上述实施例及优选实施方式,已经进行过说明的不再赘述。如以下所使用的,术语“模块”可以实现预定功能的软件和/或硬件的组合。尽管以下实施例所描述的装置较佳地以软件来实现,但是硬件,或者软件和硬件的组合的实现也是可能并被构想的。A cross-system switching device is also provided in the embodiment of the present invention. The device is used to implement the above embodiments and preferred embodiments, and the description thereof has been omitted. As used below, the term "module" may implement a combination of software and/or hardware of a predetermined function. Although the apparatus described in the following embodiments is preferably implemented in software, hardware, or a combination of software and hardware, is also possible and contemplated.
图13是根据本发明实施例的可选的跨系统的切换装置的示意图。如图13所示,该装置可以包括:获知单元131和第一发送单元132。13 is a schematic diagram of an alternative cross-system switching device in accordance with an embodiment of the present invention. As shown in FIG. 13, the apparatus may include: a learning unit 131 and a first transmitting unit 132.
获知单元131,配置为获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;The learning unit 131 is configured to learn that the user equipment UE cross-system handover, wherein the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system;
第一发送单元132,配置为息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。The first sending unit 132 is configured to send the information to the mobility management node function MME, where the MME located in the 4G system is configured to reserve resources for the UE on the radio side according to the received target bearer information.
通过上述实施例,获知单元获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;第一发送单元在UE从5G系统切换至4G系统的过程中,将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。从而解决了相关技术中在跨系统切换时由于AMF不能生成会话信息导致的无线侧不能为用户设备预留资源的技术问题,实现了在跨系统切换时在无线侧为用户设备预留资源的技术效果。Through the foregoing embodiment, the learning unit knows that the user equipment UE cross-system handover, wherein the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system; the first sending unit is in the UE. In the process of switching from the 5G system to the 4G system, the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the MME located in the 4G system is configured to use the target bearer information as the UE on the radio side. Reserve resources. Therefore, the technical problem that the wireless side cannot reserve resources for the user equipment caused by the AMF unable to generate session information during the cross-system handover in the related art is solved, and the technology for reserving resources for the user equipment on the wireless side during cross-system handover is realized. effect.
上述的装置可应用于5G系统中的AMF。The above device can be applied to AMF in a 5G system.
在上述实施例中,该装置还包括:第一保存单元,配置为在获知UE发生跨系统切换之前,接收并保存5G系统中的会话控制功能SMF发送的缺省承载信息;其中,目标承载信息至少包括缺省承载信息,缺省承载信息是在5G系统中为UE建立协议数据单元PDU会话的过程中,SMF生成的与PDU会话的缺省服务质量流Default Qos Flow对应的在4G系统中使用的承载 信息。In the above embodiment, the apparatus further includes: a first saving unit, configured to receive and save default bearer information sent by the session control function SMF in the 5G system before learning that the UE cross-system handover occurs; wherein the target bearer information At least the default bearer information is used. In the process of establishing a protocol data unit PDU session for the UE in the 5G system, the SMF generates the default service quality flow Default Qos Flow corresponding to the PDU session and is used in the 4G system. Bearer information.
可选地,第一保存单元包括:信息接收模块,配置为在接收并保存5G系统中的会话控制功能SMF发送的缺省承载信息之后,接收SMF重新发送的缺省承载信息,其中,信息接收模块当前接收到的缺省承载信息为在缺省服务质量流发生变化时,SMF生成的与变化后的缺省服务质量流对应的承载信息;替换模块,用于将保存的缺省承载信息替换为当前接收到的缺省承载信息。Optionally, the first saving unit includes: an information receiving module, configured to receive the default bearer information resent by the SMF after receiving and saving the default bearer information sent by the session control function SMF in the 5G system, where the information receiving The default bearer information currently received by the module is the bearer information corresponding to the changed default quality of service flow generated by the SMF when the default QoS flow changes; the replacement module is used to replace the saved default bearer information. Is the default bearer information currently received.
在一个可选的实施例中,该装置还包括:第二保存单元,配置为在获知UE发生跨系统切换之前,接收并保存5G系统中的SMF发送的专用承载信息;其中,目标承载信息包括缺省承载信息和专用承载信息,专用承载信息是在5G系统中为UE建立专用服务质量流Dedicated Qos Flow时,SMF生成的与专用服务质量流对应的在4G系统中使用的承载信息。In an optional embodiment, the apparatus further includes: a second saving unit configured to receive and save the dedicated bearer information sent by the SMF in the 5G system before learning that the UE cross-system handover occurs; wherein the target bearer information includes The default bearer information and the dedicated bearer information are bearer information used in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system.
在另一个可选的实施例中,该装置还包括:第二发送单元,配置为在UE由5G系统中的接入和移动性管理功能第一AMF切换至第二AMF时,将保存的UE的目标承载信息发送至第二AMF,其中,第二AMF用于保存接收到的UE的目标承载信息。In another optional embodiment, the apparatus further includes: a second sending unit configured to: when the UE is switched by the access and mobility management function in the 5G system, the first AMF to the second AMF, the UE to be saved The target bearer information is sent to the second AMF, where the second AMF is used to save the target bearer information of the received UE.
本发明实施例中还提供了一种跨系统的切换装置。该装置用于实现上述实施例及优选实施方式,已经进行过说明的不再赘述。如以下所使用的,术语“模块”可以实现预定功能的软件和/或硬件的组合。尽管以下实施例所描述的装置较佳地以软件来实现,但是硬件,或者软件和硬件的组合的实现也是可能并被构想的。A cross-system switching device is also provided in the embodiment of the present invention. The device is used to implement the above embodiments and preferred embodiments, and the description thereof has been omitted. As used below, the term "module" may implement a combination of software and/or hardware of a predetermined function. Although the apparatus described in the following embodiments is preferably implemented in software, hardware, or a combination of software and hardware, is also possible and contemplated.
图14是根据本发明实施例的可选的跨系统的切换装置的示意图。如图14所示,该装置可以包括:接收单元141和预留单元142。14 is a schematic diagram of an alternative cross-system switching device in accordance with an embodiment of the present invention. As shown in FIG. 14, the apparatus may include: a receiving unit 141 and a reservation unit 142.
接收单元141,配置为在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,其中,第一AMF位于5G系统中;The receiving unit 141 is configured to receive, in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, the target bearer of the UE sent by the first AMF of the access and mobility management function. Information, wherein the first AMF is located in the 5G system;
预留单元142,配置为按照接收到的目标承载信息为UE在无线侧预留 资源。The reservation unit 142 is configured to reserve resources on the radio side for the UE according to the received target bearer information.
通过上述实施例,接收单元在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,第一AMF位于5G系统中;预留单元按照接收到的目标承载信息为UE在无线侧预留资源。从而解决了相关技术中在跨系统切换时由于AMF不能生成会话信息导致的无线侧不能为用户设备预留资源的技术问题,实现了在跨系统切换时在无线侧为用户设备预留资源的技术效果。Through the above embodiment, the receiving unit receives the target of the UE sent by the first AMF of the access and mobility management function in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system. Carrying information, the first AMF is located in the 5G system; the reservation unit reserves resources for the UE on the radio side according to the received target bearer information. Therefore, the technical problem that the wireless side cannot reserve resources for the user equipment caused by the AMF unable to generate session information during the cross-system handover in the related art is solved, and the technology for reserving resources for the user equipment on the wireless side during cross-system handover is realized. effect.
可选地,接收单元包括:第一接收模块,配置为接收第一AMF发送的缺省承载信息;其中,目标承载信息至少包括缺省承载信息,缺省承载信息是在5G系统中为UE建立协议数据单元PDU会话的过程中,会话控制功能SMF生成的与PDU会话的缺省服务质量流Default Qos Flow对应的在4G系统中使用的承载信息。Optionally, the receiving unit includes: a first receiving module, configured to receive default bearer information sent by the first AMF; where the target bearer information includes at least default bearer information, where the default bearer information is established for the UE in the 5G system. During the protocol data unit PDU session, the session control function SMF generates bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
可选地,接收单元还包括:第二接收模块,配置为接收第一AMF发送的专用承载信息;其中,目标承载信息包括缺省承载信息和专用承载信息,专用承载信息是在5G系统中为UE建立专用服务质量流Dedicated Qos Flow时,SMF生成的与专用服务质量流对应的在4G系统中使用的承载信息。Optionally, the receiving unit further includes: a second receiving module, configured to receive the dedicated bearer information sent by the first AMF; wherein the target bearer information includes default bearer information and dedicated bearer information, where the dedicated bearer information is in the 5G system. When the UE establishes a dedicated quality of service stream (Dedicated Qos Flow), the bearer generates the bearer information used in the 4G system corresponding to the dedicated quality of service stream.
需要说明的是,上述各个模块是可以通过软件或硬件来实现的,对于后者,可以通过以下方式实现,但不限于此:上述模块均位于同一处理器中;或者,上述各个模块以任意组合的形式分别位于不同的处理器中。It should be noted that each of the above modules may be implemented by software or hardware. For the latter, the foregoing may be implemented by, but not limited to, the foregoing modules are all located in the same processor; or, the above modules are in any combination. The forms are located in different processors.
本发明的实施例还提供了一种计算机存储介质,可以简称为存储介质。可选地,在本实施例中,上述存储介质可以被设置为存储用于执行以下步骤的程序代码及应用程序等计算机可执行代码:Embodiments of the present invention also provide a computer storage medium, which may be simply referred to as a storage medium. Optionally, in this embodiment, the foregoing storage medium may be configured to store computer executable code such as program code and application program for performing the following steps:
S11,获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;S11, it is known that the user equipment UE cross-system handover, wherein the cross-system handover refers to the UE switching from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system;
S12,在UE从5G系统切换至4G系统的过程中,将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用 于按照接收到的目标承载信息为UE在无线侧预留资源。S12, in the process of the UE switching from the 5G system to the 4G system, the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the MME located in the 4G system is configured to follow the received target bearer information. The UE reserves resources on the radio side.
可选地,存储介质还被设置为存储用于执行以下步骤的程序代码:Optionally, the storage medium is further arranged to store program code for performing the following steps:
S21,在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,其中,第一AMF位于5G系统中;S21, in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, receiving the target bearer information of the UE sent by the first AMF of the access and mobility management function, where The first AMF is located in the 5G system;
S22,按照接收到的目标承载信息为UE在无线侧预留资源。S22. Reserve resources on the radio side for the UE according to the received target bearer information.
可选地,在本实施例中,上述存储介质可以包括但不限于:U盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、移动硬盘、磁碟或者光盘等各种可以存储程序代码的介质。可选地,上述存储介质为非瞬间存储介质。Optionally, in this embodiment, the foregoing storage medium may include, but not limited to, a USB flash drive, a Read-Only Memory (ROM), a Random Access Memory (RAM), a mobile hard disk, and a magnetic memory. A variety of media that can store program code, such as a disc or a disc. Optionally, the storage medium is a non-transitory storage medium.
可选地,在本实施例中,处理器根据存储介质中已存储的程序代码执行:获知用户设备UE发生跨系统切换,其中,跨系统切换是指UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;在UE从5G系统切换至4G系统的过程中,将预先保存的UE的目标承载信息发送至移动管理节点功能MME,其中,位于4G系统中的MME用于按照接收到的目标承载信息为UE在无线侧预留资源。Optionally, in this embodiment, the processor performs, according to the stored program code in the storage medium, that the user equipment UE is involved in cross-system handover, where the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system. To the fourth generation mobile communication technology 4G system; in the process of the UE switching from the 5G system to the 4G system, the target bearer information of the pre-saved UE is sent to the mobility management node function MME, where the MME located in the 4G system is used The UE reserves resources on the radio side according to the received target bearer information.
可选地,在本实施例中,处理器根据存储介质中已存储的程序代码执行:在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的UE的目标承载信息,其中,第一AMF位于5G系统中;按照接收到的目标承载信息为UE在无线侧预留资源。Optionally, in this embodiment, the processor performs, according to the stored program code in the storage medium, in a process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, And receiving, by the access and mobility management function, the target bearer information of the UE sent by the first AMF, where the first AMF is located in the 5G system; and the UE reserves resources on the radio side according to the received target bearer information.
可选地,本实施例中的具体示例可以参考上述实施例及可选实施方式中所描述的示例,本实施例在此不再赘述。For example, the specific examples in this embodiment may refer to the examples described in the foregoing embodiments and the optional embodiments, and details are not described herein again.
显然,本领域的技术人员应该明白,上述的本发明的各模块或各步骤可以用通用的计算装置来实现,它们可以集中在单个的计算装置上,或者分布在多个计算装置所组成的网络上,可选地,它们可以用计算装置可执行的程序代码来实现,从而,可以将它们存储在存储装置中由计算装置来执行,并且在某些情况下,可以以不同于此处的顺序执行所示出或描述的 步骤,或者将它们分别制作成各个集成电路模块,或者将它们中的多个模块或步骤制作成单个集成电路模块来实现。这样,本发明不限制于任何特定的硬件和软件结合。It will be apparent to those skilled in the art that the various modules or steps of the present invention described above can be implemented by a general-purpose computing device that can be centralized on a single computing device or distributed across a network of multiple computing devices. Alternatively, they may be implemented by program code executable by the computing device such that they may be stored in the storage device by the computing device and, in some cases, may be different from the order herein. The steps shown or described are performed, or they are separately fabricated into individual integrated circuit modules, or a plurality of modules or steps thereof are fabricated as a single integrated circuit module. Thus, the invention is not limited to any specific combination of hardware and software.
以上所述仅为本发明的优选实施例而已,并不用于限制本发明,对于本领域的技术人员来说,本发明可以有各种更改和变化。凡在本发明的精神和原则之内,所作的任何修改、等同替换、改进等,均应包含在本发明的保护范围之内。The above description is only the preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes can be made to the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.
工业实用性Industrial applicability
本发明实施例提供的技术方案中,若用户设备从5G系统向4G系统切换时,5G系统的AMF会将目标承载信息发送至4G系统的MME,如此4G系统接收到的目标承载系统之后,就可以成功的为用户设备预留资源,用户设备切换到4G系统之后就可以利用预留的资源进行通信,从而解决了现有技术中用户设备从5G系统切换到4G系统因为没有目标承载信息等于会话相关的信息,从而不能成功为用户设备预留资源,导致5G系统到4G系统的切换延时大或系统切换后的数据传输延时大的问题,从而具有系统切换速率高及系统切换后数据传输速率高的特点,具有积极的工业效果。且另一方面,本发明实施例提供的技术方案具有实现速率高等特点。In the technical solution provided by the embodiment of the present invention, if the user equipment switches from the 5G system to the 4G system, the AMF of the 5G system sends the target bearer information to the MME of the 4G system, and after the target bearer system received by the 4G system, The user equipment can be successfully reserved for the user equipment. After the user equipment switches to the 4G system, the reserved resources can be used for communication, thereby solving the problem that the user equipment switches from the 5G system to the 4G system in the prior art because no target bearer information is equal to the session. Relevant information, so that resources cannot be successfully reserved for the user equipment, resulting in a large handover delay of the 5G system to the 4G system or a large data transmission delay after the system switching, thereby having a high system switching rate and data transmission after system switching. The high rate features a positive industrial effect. On the other hand, the technical solution provided by the embodiment of the present invention has the characteristics of high speed and the like.

Claims (25)

  1. 一种跨系统的切换方法,包括:A cross-system switching method includes:
    第一接入和移动性管理功能AMF获知用户设备UE发生跨系统切换,其中,所述跨系统切换是指所述UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统,所述第一AMF位于所述5G系统中;The first access and mobility management function AMF learns that the user equipment UE cross-system handover, wherein the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system. The first AMF is located in the 5G system;
    在所述UE从所述5G系统切换至所述4G系统的过程中,所述第一AMF将预先保存的所述UE的目标承载信息发送至移动管理节点功能MME,其中,位于所述4G系统中的所述MME用于按照接收到的所述目标承载信息为所述UE在无线侧预留资源。In the process of the UE switching from the 5G system to the 4G system, the first AMF sends the target bearer information of the UE saved in advance to the mobility management node function MME, where the 4G system is located. The MME is configured to reserve resources on the radio side of the UE according to the received target bearer information.
  2. 根据权利要求1所述的方法,其中,在所述第一AMF获知所述UE发生跨系统切换之前,所述方法还包括:The method according to claim 1, wherein before the first AMF learns that the UE has a cross-system handover, the method further includes:
    所述第一AMF接收并保存所述5G系统中的会话控制功能SMF发送的缺省承载信息;The first AMF receives and saves default bearer information sent by the session control function SMF in the 5G system;
    其中,所述目标承载信息至少包括所述缺省承载信息,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话的过程中,所述SMF生成的与所述PDU会话的缺省服务质量流Default Qos Flow对应的在所述4G系统中使用的承载信息。The target bearer information includes at least the default bearer information, where the default bearer information is generated in the process of establishing a protocol data unit PDU session for the UE in the 5G system. The bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  3. 根据权利要求2所述的方法,其中,在所述第一AMF接收并保存所述5G系统中的会话控制功能SMF发送的缺省承载信息之后,所述方法还包括:The method of claim 2, wherein after the first AMF receives and saves the default bearer information sent by the session control function SMF in the 5G system, the method further includes:
    所述第一AMF接收所述SMF重新发送的缺省承载信息,其中,所述第一AMF当前接收到的缺省承载信息为在所述缺省服务质量流发生变化时,所述SMF生成的与变化后的所述缺省服务质量流对应的承载信息;The first AMF receives the default bearer information that is sent by the SMF, where the default bearer information currently received by the first AMF is generated by the SMF when the default quality of service flow changes. Bearer information corresponding to the changed default quality of service flow;
    所述第一AMF将保存的缺省承载信息替换为当前接收到的缺省承载信息。The first AMF replaces the saved default bearer information with the currently received default bearer information.
  4. 根据权利要求1所述的方法,其中,在所述第一AMF获知所述UE发生跨系统切换之前,所述方法还包括:The method according to claim 1, wherein before the first AMF learns that the UE has a cross-system handover, the method further includes:
    所述第一AMF接收并保存所述5G系统中的SMF发送的专用承载信息;The first AMF receives and saves dedicated bearer information sent by the SMF in the 5G system;
    其中,所述目标承载信息包括缺省承载信息和所述专用承载信息,所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中使用的承载信息。The target bearer information includes default bearer information and the dedicated bearer information, where the dedicated bearer information is generated by the SMF when a dedicated quality of service flow (Dedicated Qos Flow) is established for the UE in the 5G system. Bearer information used in the 4G system corresponding to the dedicated quality of service stream.
  5. 根据权利要求1至4中任意一项所述的方法,其中,所述方法还包括:The method of any one of claims 1 to 4, wherein the method further comprises:
    在所述UE由所述第一AMF切换至所述5G系统中的第二AMF时,所述第一AMF将保存的所述UE的目标承载信息发送至所述第二AMF,其中,所述第二AMF用于保存接收到的所述UE的目标承载信息。When the UE is switched by the first AMF to the second AMF in the 5G system, the first AMF sends the saved target bearer information of the UE to the second AMF, where the The second AMF is configured to save the received target bearer information of the UE.
  6. 一种跨系统的切换方法,其中,包括:A cross-system switching method, including:
    在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,移动管理节点功能MME接收接入和移动性管理功能第一AMF发送的所述UE的目标承载信息,其中,所述第一AMF位于所述5G系统中,所述MME位于所述4G系统中;In the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, the mobility management node function MME receives the target of the UE sent by the access and mobility management function first AMF. Carrying information, wherein the first AMF is located in the 5G system, and the MME is located in the 4G system;
    所述MME按照接收到的所述目标承载信息为所述UE在无线侧预留资源。The MME reserves resources for the UE on the radio side according to the received target bearer information.
  7. 根据权利要求6所述的方法,其中,所述MME接收所述第一AMF发送的所述UE的目标承载信息包括:The method according to claim 6, wherein the receiving, by the MME, the target bearer information of the UE that is sent by the first AMF includes:
    所述MME接收所述第一AMF发送的缺省承载信息;Receiving, by the MME, default bearer information sent by the first AMF;
    其中,所述目标承载信息至少包括所述缺省承载信息,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话的过程 中,会话控制功能SMF生成的与所述PDU会话的缺省服务质量流Default Qos Flow对应的在所述4G系统中使用的承载信息。The target bearer information includes at least the default bearer information, where the default bearer information is generated by the session control function SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system. The bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  8. 根据权利要求7所述的方法,其中,所述MME接收所述第一AMF发送的所述UE的目标承载信息还包括:The method according to claim 7, wherein the receiving, by the MME, the target bearer information of the UE that is sent by the first AMF further includes:
    所述MME接收所述第一AMF发送的专用承载信息;Receiving, by the MME, dedicated bearer information sent by the first AMF;
    其中,所述目标承载信息包括所述缺省承载信息和所述专用承载信息,所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中使用的承载信息。The target bearer information includes the default bearer information and the dedicated bearer information, where the dedicated bearer information is used in the 5G system to establish a dedicated quality of service stream (Dedicated Qos Flow) for the UE. The generated bearer information used in the 4G system corresponding to the dedicated quality of service stream.
  9. 一种跨系统的切换装置,其中,包括:A cross-system switching device, comprising:
    获知单元,配置为获知用户设备UE发生跨系统切换,其中,所述跨系统切换是指所述UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;The learning unit is configured to learn that the user equipment UE cross-system handover occurs, where the cross-system handover refers to that the UE switches from the fifth-generation mobile communication technology 5G system to the fourth-generation mobile communication technology 4G system;
    第一发送单元,配置为在所述UE从所述5G系统切换至所述4G系统的过程中,将预先保存的所述UE的目标承载信息发送至移动管理节点功能MME,其中,位于所述4G系统中的所述MME用于按照接收到的所述目标承载信息为所述UE在无线侧预留资源。a first sending unit, configured to send the target bearer information of the UE saved in advance to the mobility management node function MME, where the UE is in the process of switching from the 5G system to the 4G system, where The MME in the 4G system is configured to reserve resources on the radio side of the UE according to the received target bearer information.
  10. 根据权利要求9所述的装置,其中,所述装置还包括:The apparatus of claim 9 wherein said apparatus further comprises:
    第一保存单元,配置为在获知所述UE发生跨系统切换之前,接收并保存所述5G系统中的会话控制功能SMF发送的缺省承载信息;a first saving unit, configured to receive and save default bearer information sent by the session control function SMF in the 5G system, before learning that the UE cross-system handover occurs;
    其中,所述目标承载信息至少包括所述缺省承载信息,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话的过程中,所述SMF生成的与所述PDU会话的缺省服务质量流Default Qos Flow对应的在所述4G系统中使用的承载信息。The target bearer information includes at least the default bearer information, where the default bearer information is generated in the process of establishing a protocol data unit PDU session for the UE in the 5G system. The bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  11. 根据权利要求10所述的装置,其中,所述第一保存单元包括:The apparatus of claim 10, wherein the first saving unit comprises:
    信息接收模块,配置为在接收并保存所述5G系统中的会话控制功能SMF发送的缺省承载信息之后,接收所述SMF重新发送的缺省承载信息,其中,所述信息接收模块当前接收到的缺省承载信息为在所述缺省服务质量流发生变化时,所述SMF生成的与变化后的所述缺省服务质量流对应的承载信息;The information receiving module is configured to receive the default bearer information resent by the SMF after receiving and saving the default bearer information sent by the session control function SMF in the 5G system, where the information receiving module currently receives The default bearer information is the bearer information corresponding to the changed default quality of service flow generated by the SMF when the default quality of service flow changes;
    替换模块,配置为将保存的缺省承载信息替换为当前接收到的缺省承载信息。The replacement module is configured to replace the saved default bearer information with the currently received default bearer information.
  12. 根据权利要求9所述的装置,其中,所述装置还包括:The apparatus of claim 9 wherein said apparatus further comprises:
    第二保存单元,配置为在获知所述UE发生跨系统切换之前,接收并保存所述5G系统中的SMF发送的专用承载信息;a second saving unit, configured to receive and save dedicated bearer information sent by the SMF in the 5G system, before learning that the UE cross-system handover occurs;
    其中,所述目标承载信息包括缺省承载信息和所述专用承载信息,所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中使用的承载信息。The target bearer information includes default bearer information and the dedicated bearer information, where the dedicated bearer information is generated by the SMF when a dedicated quality of service flow (Dedicated Qos Flow) is established for the UE in the 5G system. Bearer information used in the 4G system corresponding to the dedicated quality of service stream.
  13. 根据权利要求9至12中任意一项所述的装置,其中,所述装置还包括:The device according to any one of claims 9 to 12, wherein the device further comprises:
    第二发送单元,配置为在所述UE由所述5G系统中的接入和移动性管理功能第一AMF切换至第二AMF时,将保存的所述UE的目标承载信息发送至所述第二AMF,其中,所述第二AMF用于保存接收到的所述UE的目标承载信息。a second sending unit, configured to: when the UE is switched by the access and mobility management function first AMF to the second AMF in the 5G system, send the saved target bearer information of the UE to the And a second AMF, where the second AMF is used to save the received target bearer information of the UE.
  14. 一种跨系统的切换装置,其中,包括:A cross-system switching device, comprising:
    接收单元,配置为在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的所述UE的目标承载信息,其中,所述第一AMF位于所述5G系统中;The receiving unit is configured to receive, in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system, receiving the target of the UE sent by the access and mobility management function first AMF Carrying information, wherein the first AMF is located in the 5G system;
    预留单元,配置为按照接收到的所述目标承载信息为所述UE在无线侧预留资源。The reservation unit is configured to reserve resources on the radio side of the UE according to the received target bearer information.
  15. 根据权利要求14所述的装置,其中,所述接收单元包括:The apparatus of claim 14, wherein the receiving unit comprises:
    第一接收模块,配置为接收所述第一AMF发送的缺省承载信息;The first receiving module is configured to receive default bearer information sent by the first AMF;
    其中,所述目标承载信息至少包括所述缺省承载信息,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话的过程中,会话控制功能SMF生成的与所述PDU会话的缺省服务质量流Default Qos Flow对应的在所述4G系统中使用的承载信息。The target bearer information includes at least the default bearer information, where the default bearer information is generated by the session control function SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system. The bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  16. 根据权利要求15所述的装置,其中,所述接收单元还包括:The apparatus according to claim 15, wherein the receiving unit further comprises:
    第二接收模块,配置为接收所述第一AMF发送的专用承载信息;a second receiving module, configured to receive dedicated bearer information sent by the first AMF;
    其中,所述目标承载信息包括所述缺省承载信息和所述专用承载信息,所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中使用的承载信息。The target bearer information includes the default bearer information and the dedicated bearer information, where the dedicated bearer information is used in the 5G system to establish a dedicated quality of service stream (Dedicated Qos Flow) for the UE. The generated bearer information used in the 4G system corresponding to the dedicated quality of service stream.
  17. 一种接入和移动性管理功能模块,其中,包括:An access and mobility management function module, including:
    第一处理器;First processor;
    配置为存储所述第一处理器可执行指令的第一存储器;a first memory configured to store the first processor executable instructions;
    配置为根据所述第一处理器的控制进行信息收发通信的第一传输装置;a first transmission device configured to perform information transceiving communication according to control of the first processor;
    其中,所述第一处理器用于执行以下操作:获知用户设备UE发生跨系统切换,其中,所述跨系统切换是指所述UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统;在所述UE从所述5G系统切换至所述4G系统的过程中,将预先保存的所述UE的目标承载信息发送至移动管理节点功能MME,其中,位于所述4G系统中的所述MME用于按照接收到的所述目标承载信息为所述UE在无线侧预留资源。The first processor is configured to: perform a cross-system handover of the user equipment UE, where the cross-system handover refers to that the UE switches from a fifth-generation mobile communication technology 5G system to a fourth-generation mobile communication. a technology 4G system; in the process of the UE switching from the 5G system to the 4G system, the target bearer information of the UE saved in advance is sent to a mobility management node function MME, where the 4G system is located in the 4G system The MME is configured to reserve resources on the radio side of the UE according to the received target bearer information.
  18. 根据权利要求17所述的接入和移动性管理功能模块,其中,所述第一处理器还配置为执行以下操作:The access and mobility management function module of claim 17, wherein the first processor is further configured to perform the following operations:
    接收并保存所述5G系统中的会话控制功能SMF发送的缺省承载信息;Receiving and saving default bearer information sent by the session control function SMF in the 5G system;
    其中,所述目标承载信息至少包括所述缺省承载信息,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话的过程中,所述SMF生成的与所述PDU会话的缺省服务质量流Default Qos Flow对应的在所述4G系统中使用的承载信息。The target bearer information includes at least the default bearer information, where the default bearer information is generated in the process of establishing a protocol data unit PDU session for the UE in the 5G system. The bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  19. 一种移动管理节点功能模块,其中,包括:A mobile management node function module, comprising:
    第二处理器;Second processor;
    配置为存储所述第二处理器可执行指令的第二存储器;a second memory configured to store the second processor executable instructions;
    配置为根据所述第二处理器的控制进行信息收发通信的第二传输装置;a second transmission device configured to perform information transceiving communication according to control of the second processor;
    其中,所述第二处理器配置为执行以下操作:在用户设备UE从第五代移动通讯技术5G系统切换至第四代移动通讯技术4G系统的过程中,接收接入和移动性管理功能第一AMF发送的所述UE的目标承载信息,其中,所述第一AMF位于所述5G系统中;按照接收到的所述目标承载信息为所述UE在无线侧预留资源。The second processor is configured to perform the following operations: receiving the access and mobility management function in the process of the user equipment UE switching from the fifth generation mobile communication technology 5G system to the fourth generation mobile communication technology 4G system The target bearer information of the UE that is sent by the AMF, where the first AMF is located in the 5G system; and the UE reserves resources on the radio side according to the received target bearer information.
  20. 根据权利要求19所述的移动管理节点功能模块,其中,所述第二处理器还配置为执行以下操作:The mobility management node functional module of claim 19, wherein the second processor is further configured to perform the following operations:
    接收所述第一AMF发送的缺省承载信息;Receiving default bearer information sent by the first AMF;
    其中,所述目标承载信息至少包括所述缺省承载信息,所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话的过程中,会话控制功能SMF生成的与所述PDU会话的缺省服务质量流Default Qos Flow对应的在所述4G系统中使用的承载信息。The target bearer information includes at least the default bearer information, where the default bearer information is generated by the session control function SMF in the process of establishing a protocol data unit PDU session for the UE in the 5G system. The bearer information used in the 4G system corresponding to the default quality of service flow Default Qos Flow of the PDU session.
  21. 一种跨系统的切换方法,包括:A cross-system switching method includes:
    用户设备UE在第五代移动通讯技术5G系统中,从第一接入和移动性管理功能AMF接收与缺省服务质量流Default Qos Flow对应的目标承载信息,其中,所述目标承载信息为:所述UE在从5G系统切换到第四代移动通讯技术4G系统后使用的承载信息。The user equipment UE receives the target bearer information corresponding to the default QoS flow Default Qos Flow from the first access and mobility management function AMF in the fifth generation mobile communication technology 5G system, where the target bearer information is: Bearer information used by the UE after switching from the 5G system to the 4th generation mobile communication technology 4G system.
  22. 根据权利要求21所述的方法,其中,所述目标承载信息,是所述第一AMF从会话管理功能SMF接收的。The method of claim 21 wherein said target bearer information is received by said first AMF from a session management function SMF.
  23. 根据权利要求22所述的方法,其中,The method of claim 22, wherein
    所述目标承载信息包括缺省承载信息和专用承载信息;The target bearer information includes default bearer information and dedicated bearer information;
    所述缺省承载信息是在所述5G系统中为所述UE建立协议数据单元PDU会话时,所述SMF生成的与所述缺省服务质量流对应的在所述4G系统中缺省承载的承载信息;The default bearer information is a default bearer in the 4G system corresponding to the default quality of service stream generated by the SMF when the protocol data unit PDU session is established for the UE in the 5G system. Carrying information;
    所述专用承载信息是在所述5G系统中为所述UE建立专用服务质量流Dedicated Qos Flow时,所述SMF生成的与所述专用服务质量流对应的在所述4G系统中专用承载的承载信息。The dedicated bearer information is a bearer dedicated to the bearer in the 4G system corresponding to the dedicated quality of service stream generated by the SMF when the dedicated quality of service stream (Dedicated Qos Flow) is established for the UE in the 5G system. information.
  24. 一种跨系统的切换装置,包括:A cross-system switching device comprising:
    接收单元,配置为用户设备UE在第五代移动通讯技术5G系统中,接收与缺省服务质量流Default Qos Flow对应的目标承载信息,其中,所述目标承载信息为:所述UE在从5G系统切换到第四代移动通讯技术4G系统后使用的承载信息。The receiving unit is configured to receive the target bearer information corresponding to the default QoS flow Default Qos Flow in the fifth generation mobile communication technology 5G system, where the target bearer information is: the UE is in the slave 5G The bearer information used after the system switches to the 4G mobile communication technology 4G system.
  25. 一种计算机存储介质,所述计算机存储介质存储有计算机可执行程序;所述计算机可执行程序被执行后,能够实现权利要求1至5或6至8或21至23任一项提供的跨系统的切换方法。A computer storage medium storing a computer executable program; the computer executable program being capable of implementing the cross system provided by any one of claims 1 to 5 or 6 to 8 or 21 to 23 Switching method.
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