WO2024078305A1 - 通信方法、通信装置及通信系统 - Google Patents

通信方法、通信装置及通信系统 Download PDF

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Publication number
WO2024078305A1
WO2024078305A1 PCT/CN2023/120862 CN2023120862W WO2024078305A1 WO 2024078305 A1 WO2024078305 A1 WO 2024078305A1 CN 2023120862 W CN2023120862 W CN 2023120862W WO 2024078305 A1 WO2024078305 A1 WO 2024078305A1
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Prior art keywords
network element
shared data
network
identification information
information
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PCT/CN2023/120862
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English (en)
French (fr)
Inventor
丁辉
景昊
王毓芳
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华为技术有限公司
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Publication of WO2024078305A1 publication Critical patent/WO2024078305A1/zh

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/06Optimizing the usage of the radio link, e.g. header compression, information sizing, discarding information
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W60/00Affiliation to network, e.g. registration; Terminating affiliation with the network, e.g. de-registration

Definitions

  • the present application relates to the field of wireless communication technology, and in particular to a communication method, a communication device and a communication system.
  • a network repository function (NRF) network element in order to realize the registration process of network element services, a network repository function (NRF) network element is introduced.
  • the process is as follows: the network function (NF) network element sends a network element registration request to the NRF network element.
  • the network element registration request includes network element parameter information (NFprofile), and then NRF stores the network element parameter information.
  • NFprofile network element parameter information
  • the present application provides a communication method, a communication device and a communication system, which are used to reduce the bandwidth resource overhead and signaling overhead of a network storage network element.
  • an embodiment of the present application provides a communication method, which can be executed by a network storage network element or a chip applied to a network storage network element.
  • the network storage network element receives a network element registration request from a first network element, the network element registration request includes network element parameter information of the first network element, the network element parameter information includes identification information of shared data and identification information of the first network element, and the network element parameter information does not include the shared data corresponding to the identification information of the shared data; the network storage network element stores the network element parameter information.
  • the network element parameter information sent does not carry shared data but carries identification information of the shared data, which can reduce the size of the network element parameter information, thereby reducing the bandwidth resource overhead and signaling overhead between the first network element and the network storage network element.
  • the network storage element has stored the shared data.
  • the network storage element only needs to store one copy of the shared data, which can reduce the occupation of storage resources of the network storage element and improve resource utilization efficiency.
  • the network storage network element sends a subscription request to the central node, the subscription request includes identification information of the shared data, and the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the above solution can ensure that the network storage network element stores the latest shared data by subscribing to updated shared data, which is beneficial for other network elements to obtain correct data from the network storage network element.
  • the network storage network element obtains the shared data and stores the shared data.
  • the network storage network element when the network storage network element does not store shared data corresponding to the identification information of the shared data, the network storage network element obtains and stores the shared data, and the network storage network element only needs to store one copy of the shared data, which can reduce the occupancy of the storage resources of the network storage network element and improve resource utilization efficiency.
  • the network storage network element obtains the shared data from the first network element.
  • the network storage network element sends a subscription request to the first network element, the subscription request includes identification information of the shared data, and the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the above solution can ensure that the network storage network element stores the latest shared data by subscribing to updated shared data, which is beneficial for other network elements to obtain correct data from the network storage network element.
  • the registration request also includes information of a central node; and the network storage network element obtains the shared data from the central node.
  • the network storage network element sends a subscription request to the central node, and the subscription request includes the shared data
  • the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the above solution can ensure that the network storage network element stores the latest shared data by subscribing to updated shared data, which is beneficial for other network elements to obtain correct data from the network storage network element.
  • the registration request further includes a sharing level, where the sharing level is used to indicate a granularity of data sharing.
  • the above scheme shares data according to the sharing level, which helps to achieve flexibility in the data sharing method.
  • the registration request also includes identification information of the first network element set to which the first network element belongs, and the sharing level is specifically used to indicate data sharing at the granularity of the network element set; the shared data stored by the network storage network element corresponds to the identification information of the first network element set and the identification information of the shared data.
  • the registration request also includes identification information of the network corresponding to the first network element, and the sharing level is specifically used to indicate data sharing at a network granularity, and the identification information of the network includes a data network name and/or a network slice identifier; the shared data stored in the network storage network element corresponds to the identification information of the network and the identification information of the shared data.
  • the registration request also includes information of the central node, and the sharing level is specifically used to indicate data sharing at the granularity of the central node; the shared data stored in the network storage element corresponds to the information of the central node and the identification information of the shared data.
  • the network storage network element receives a network element discovery request from a second network element, wherein the network element discovery request includes a network element type and a query condition; the network storage network element sends a network element discovery response to the second network element, wherein the network element discovery response includes identification information of the first network element and identification information of the shared data, wherein the identification information of the shared data is used by the second network element to obtain the shared data; wherein the type of the first network element is the same as the type of the network element, and the first network element meets the query condition.
  • the network storage network element when the network storage network element returns the queried information of the first network element to the second network element, it does not need to send the shared data corresponding to the first network element to the second network element, but instead sends the identification information of the shared data corresponding to the first network element to the second network element, thereby reducing bandwidth resource overhead and signaling overhead.
  • the network element discovery response also includes information of a central node, and the information of the central node is used by the second network element to obtain the shared data from the central node.
  • the second network element can obtain shared data from the central node instead of the data storage network element. Therefore, the data storage network element does not need to store the shared data, which can reduce the storage resource occupation of the data storage network element.
  • an embodiment of the present application provides a communication device, which may be a network storage network element, or a chip for a network storage network element.
  • the device has the function of implementing any implementation method of the first aspect above.
  • the function may be implemented by hardware, or by hardware executing corresponding software implementation.
  • the hardware or software includes one or more modules corresponding to the above functions.
  • an embodiment of the present application provides a communication device, comprising a processor coupled to a memory, the processor being used to call a program stored in the memory to execute any implementation method in the first aspect.
  • the memory may be located inside the device or outside the device.
  • the processor may be one or more.
  • an embodiment of the present application provides a communication device, comprising a processor and a memory; the memory is used to store computer instructions, and when the device is running, the processor executes the computer instructions stored in the memory so that the device executes any implementation method in the above-mentioned first aspect.
  • an embodiment of the present application provides a communication device, comprising a unit or means for executing each step of any implementation method in the above-mentioned first aspect.
  • an embodiment of the present application provides a communication device, including a processor and an interface circuit, wherein the processor is used to communicate with other devices through the interface circuit and execute any implementation method in the first aspect.
  • the processor includes one or more.
  • an embodiment of the present application further provides a computer-readable storage medium, wherein instructions are stored in the computer-readable storage medium, and when the computer-readable storage medium is run on a communication device, any implementation method in the above-mentioned first aspect is executed.
  • an embodiment of the present application further provides a computer program product, which includes a computer program or instructions.
  • a computer program product which includes a computer program or instructions.
  • an embodiment of the present application further provides a chip system, comprising: a processor, configured to execute any implementation method in the above-mentioned first aspect.
  • an embodiment of the present application further provides a communication system, which includes a network storage network element for executing any implementation method of the above-mentioned first aspect, and a first network element for sending a network element registration request to the network storage network element.
  • an embodiment of the present application further provides a communication method, wherein a first network element sends a network element registration request to a network storage network element, wherein the network element registration request includes network element parameter information of the first network element, wherein the network element parameter information includes identification information of the shared data and the first network element.
  • the identification information of a network element, the network element parameter information does not include the shared data corresponding to the identification information of the shared data; the network storage network element receives the network element registration request sent by the first network element, and stores the network element parameter information carried by the network element registration request.
  • the network storage network element can execute any implementation method of the first aspect above.
  • FIG1 is a schematic diagram of a communication system provided in an embodiment of the present application.
  • FIG2 is a schematic diagram of a 5G network architecture based on a service-oriented architecture
  • FIG3 is a schematic diagram of a 5G network architecture based on a point-to-point interface
  • FIG4 is a flow chart of a communication method provided in an embodiment of the present application.
  • FIG5 is a flow chart of a communication method provided in an embodiment of the present application.
  • FIG6 is a schematic diagram of a communication device provided in an embodiment of the present application.
  • FIG. 7 is a schematic diagram of a communication device provided in an embodiment of the present application.
  • the present application provides a communication system.
  • the system includes a network storage network element and a first network element.
  • the communication system also includes a second network element.
  • the system shown in FIG. 1 can be used in the 5G network architecture shown in FIG. 2 or FIG. 3 .
  • it can also be used in future network architectures, such as the sixth generation (6G) network architecture, etc., and this application does not limit this.
  • 6G sixth generation
  • the network storage network element in Figure 1 can be the NRF network element in Figure 2 or Figure 3, or it can be a network element with the function of an NRF network element in future communications such as 6G communications, and this application does not limit this.
  • the first network element in Figure 1 is a NF network element, such as the AMF network element, SMF network element, UPF network element or UDM network element in Figure 2 or 3, or a network element with the functions of AMF network element, SMF network element, UPF network element or UDM network element in future communications such as 6G communications. This application does not limit this.
  • the second network element NF network element in Figure 1 can be, for example, the AMF network element, SMF network element, UPF network element or UDM network element in Figure 2 or 3, or it can be a network element with the functions of AMF network element, SMF network element, UPF network element or UDM network element in future communications such as 6G communications, and this application does not limit this.
  • a first network element is used to send a network element registration request to a network storage network element, wherein the network element registration request includes network element parameter information of the first network element, the network element parameter information includes identification information of shared data and identification information of the first network element, and the network element parameter information does not include the shared data corresponding to the identification information of the shared data; a network storage network element is used to store the network element parameter information.
  • the network storage element has stored the shared data.
  • the network storage network element is also used to send a subscription request to the central node, the subscription request includes identification information of the shared data, and the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the network storage network element is also used to obtain the shared data and store the shared data.
  • the network storage network element is specifically used to obtain the shared data from the first network element.
  • the network storage network element is also used to send a subscription request to the first network element, and the subscription request includes identification information of the shared data, and the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the registration request also includes information of a central node; the network storage network element is specifically used to obtain the shared data from the central node.
  • the network storage network element is also used to send a subscription request to the central node, the subscription request includes identification information of the shared data, and the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the registration request further includes a sharing level, where the sharing level is used to indicate the granularity of data sharing.
  • the registration request also includes identification information of the first network element set to which the first network element belongs, and the sharing level is specifically used to indicate data sharing at the granularity of the network element set; the shared data stored by the network storage network element corresponds to the identification information of the first network element set and the identification information of the shared data.
  • the registration request also includes identification information of the network corresponding to the first network element, and the sharing level is specifically used to indicate data sharing at a network granularity, and the identification information of the network includes a data network name and/or a network slice identifier; the shared data stored in the network storage network element corresponds to the identification information of the network and the identification information of the shared data.
  • the registration request also includes information of the central node, and the sharing level is specifically used to indicate the central node.
  • the shared data stored in the network storage element corresponds to the information of the central node and the identification information of the shared data.
  • the second network element is used to send a network element discovery request to a network storage network element, and the network element discovery request includes a network element type and a query condition;
  • the network storage network element is also used to send a network element discovery response to the second network element, and the network element discovery response includes identification information of the first network element and identification information of the shared data, and the identification information of the shared data is used by the second network element to obtain the shared data; wherein the type of the first network element is the same as the type of the network element, and the first network element meets the query condition.
  • the network element discovery response also includes information of a central node, and the information of the central node is used by the second network element to obtain the shared data from the central node.
  • the interaction between the various network elements in the system and the specific execution can refer to the following method embodiment, which will not be repeated here.
  • 3GPP 3rd Generation Partnership Project
  • 5G network architecture next generation mobile communication network system
  • This architecture not only supports the wireless access technology defined by the 3GPP standard group (such as long term evolution (LTE) access technology, 5G radio access network (RAN) access technology, etc.) to access the 5G core network (CN), but also supports the use of non-3GPP (non-3GPP) access technology through non-3GPP conversion function (N3IWF) or next generation access gateway (next generation packet data gateway, ngPDG) to access the core network.
  • LTE long term evolution
  • RAN radio access network
  • ngPDG next generation packet data gateway
  • FIG 2 is a schematic diagram of a 5G network architecture based on a service-oriented architecture.
  • the 5G network architecture shown in Figure 2 may include access network equipment and core network equipment. Terminal equipment accesses the data network (DN) through the access network equipment and the core network equipment.
  • DN data network
  • the core network equipment includes but is not limited to some or all of the following network elements: authentication server function (AUSF) network element (not shown in the figure), unified data management (UDM) network element, unified data repository (UDR) network element, NRF network element (not shown in the figure), network exposure function (NEF) network element (not shown in the figure), application function (AF) network element, policy control function (PCF) network element, access and mobility management function (AMF) network element, session management function (SMF) network element, user plane function (UPF) network element, binding support function (BSF) network element (not shown in the figure).
  • AUSF authentication server function
  • UDM unified data management
  • UDR unified data repository
  • NRF network exposure function
  • AF application function
  • PCF policy control function
  • AMF access and mobility management function
  • SMF session management function
  • UPF user plane function
  • BSF binding support function
  • Terminal devices can be user equipment (UE), mobile stations, mobile terminal devices, etc. Terminal devices can be widely used in various scenarios, such as device-to-device (D2D), vehicle to everything (V2X) communication, machine-type communication (MTC), Internet of things (IOT), virtual reality, augmented reality, industrial control, autonomous driving, telemedicine, smart grid, smart furniture, smart office, smart wear, smart transportation, smart city, etc. Terminal devices can be mobile phones, tablet computers, computers with wireless transceiver functions, wearable devices, vehicles, urban air vehicles (such as drones, helicopters, etc.), ships, robots, robotic arms, smart home devices, etc.
  • D2D device-to-device
  • V2X vehicle to everything
  • MTC machine-type communication
  • IOT Internet of things
  • virtual reality virtual reality
  • augmented reality industrial control
  • telemedicine smart grid
  • smart furniture smart office
  • smart wear smart transportation
  • smart city smart city, etc.
  • Terminal devices can be mobile phones, tablet computers, computers with wireless transceiver functions, wear
  • Access network equipment can be wireless access network equipment (RAN equipment) or wired access network equipment.
  • wireless access network equipment includes 3GPP access network equipment, untrusted non-3GPP access network equipment and trusted non-3GPP access network equipment.
  • 3GPP access network equipment includes but is not limited to: evolved NodeB (eNodeB) in LTE, next generation NodeB (gNB) in 5G mobile communication system, base station in future mobile communication system or module or unit that completes part of the functions of base station, such as centralized unit (CU), distributed unit (DU), etc.
  • Untrusted non-3GPP access network equipment includes but is not limited to: untrusted non-3GPP access gateway or N3IWF equipment, untrusted wireless local area network (WLAN) access point (AP), switch, router.
  • WLAN wireless local area network
  • AP untrusted wireless local area network
  • Trusted non-3GPP access network equipment includes but is not limited to: trusted non-3GPP access gateway, trusted WLAN AP, switch, router.
  • Wired access network equipment includes but is not limited to: wireline access gateway, fixed-line telephone network equipment, switches, and routers.
  • the access network equipment and terminal equipment can be fixed or movable.
  • the access network equipment and terminal equipment can be deployed on land, including indoors or outdoors, handheld or vehicle-mounted; they can also be deployed on the water surface; they can also be deployed on airplanes, balloons and artificial satellites in the air.
  • the embodiments of the present application do not limit the application scenarios of the access network equipment and terminal equipment.
  • the AMF network element performs functions such as mobility management or access authentication/authorization. In addition, it is also responsible for transmitting user policies between terminal devices and PCF.
  • the SMF network element includes functions such as performing session management, executing control policies issued by the PCF network element, selecting UPF network elements, or allocating Internet Protocol (IP) addresses to terminal devices.
  • functions such as performing session management, executing control policies issued by the PCF network element, selecting UPF network elements, or allocating Internet Protocol (IP) addresses to terminal devices.
  • IP Internet Protocol
  • UPF network element including the completion of user plane data forwarding, session/flow-level billing statistics, or bandwidth limitation and other functions.
  • UDM network element including execution and management of contract data, or user access authorization and other functions.
  • UDR includes functions for accessing data such as contract data, policy data, or application data.
  • NEF network element is used to support the opening of capabilities and events.
  • AF network elements transmit the requirements of the application side to the network side, such as QoS requirements or user status event subscriptions.
  • AF can be a third-party functional entity or an application service deployed by an operator, such as IP Multimedia Subsystem (IMS) voice call service.
  • IMS IP Multimedia Subsystem
  • AF network elements include AF network elements in the core network (i.e., AF network elements of operators) and third-party AF network elements (such as an enterprise's application server).
  • the PCF network element includes policy control functions such as billing for sessions and service flow levels, QoS bandwidth guarantee and mobility management, or terminal device policy decision-making.
  • PCF network elements include access and mobility management policy control function (AM PCF) network elements and session management policy control function (SM PCF) network elements.
  • AM PCF access and mobility management policy control function
  • SM PCF session management policy control function
  • the AM PCF network element is used to formulate AM policies and user policies for terminal devices.
  • the AM PCF network element can also be called a policy control network element that provides services for terminal devices (PCF for a UE).
  • the SM PCF network element is used to formulate session management policies (session management policies, SM policies) for sessions.
  • the SM PCF network element can also be called a policy control network element that provides services for protocol data unit (PDU) sessions ((PCF for a PDU session)).
  • PDU protocol data unit
  • NRF network elements can be used to provide network element discovery functions and provide network element information corresponding to the network element type based on requests from other network elements. NRF network elements also provide network element management services, such as network element registration, update, deregistration, or network element status subscription and push.
  • BSF network element can provide BSF service registration/deregistration/update, connection detection with NRF network element, session binding information creation, terminal device information acquisition, session binding information query for duplicate IP addresses, etc.
  • the AUSF network element is responsible for authenticating users to determine whether users or devices are allowed to access the network.
  • DN is a network outside the operator network.
  • the operator network can access multiple DNs. Multiple services can be deployed on DN, which can provide data and/or voice services to terminal devices.
  • DN is the private network of a smart factory.
  • the sensors installed in the workshop of the smart factory can be terminal devices.
  • the control server of the sensors is deployed in DN, and the control server can provide services for the sensors.
  • the sensors can communicate with the control server, obtain instructions from the control server, and transmit the collected sensor data to the control server according to the instructions.
  • DN is the internal office network of a company.
  • the mobile phones or computers of the company's employees can be terminal devices.
  • the employees' mobile phones or computers can access information and data resources on the company's internal office network.
  • Npcf, Nudr, Nudm, Naf, Namf, and Nsmf are service-oriented interfaces provided by the above PCF, UDR, UDM, AF, AMF, and SMF, respectively, for invoking corresponding service-oriented operations.
  • N1, N2, N3, N4, and N6 are interface serial numbers, and the meanings of these interface serial numbers are as follows:
  • N1 The interface between the AMF network element and the terminal device, which can be used to transmit non-access stratum (NAS) signaling (such as QoS rules from the AMF network element) to the terminal device.
  • NAS non-access stratum
  • N2 The interface between the AMF network element and the access network equipment, which can be used to transmit wireless bearer control information from the core network side to the access network equipment.
  • N3 The interface between the access network equipment and the UPF network element, mainly used to transmit uplink and downlink user plane data between the access network equipment and the UPF network element.
  • N4 The interface between the SMF network element and the UPF network element can be used to transmit information between the control plane and the user plane, including controlling the issuance of forwarding rules, QoS rules, traffic statistics rules, etc. for the user plane and reporting of information on the user plane.
  • N6 The interface between UPF network element and DN, used to transmit the uplink and downlink user data flows between UPF network element and DN.
  • Figure 3 is a schematic diagram of a 5G network architecture based on a point-to-point interface.
  • the functions of the network elements therein can be referred to the functions of the corresponding network elements in Figure 2, and will not be repeated here.
  • the main difference between Figure 3 and Figure 2 is that the interface between the control plane network elements in Figure 2 is a service-oriented interface, while the interface between the control plane network elements in Figure 3 is a point-to-point interface.
  • N5 The interface between the AF network element and the PCF network element, which can be used to send application service requests and report network events.
  • N7 The interface between PCF network element and SMF network element, which can be used to send PDU session granularity and service data flow granularity control strategy.
  • N8 The interface between AMF network element and UDM network element, which can be used by AMF network element to obtain access and mobility management related contract data and authentication data from UDM network element, and AMF to register terminal equipment mobility management related information with UDM.
  • N9 User plane interface between UPF network elements, used to transmit uplink and downlink user data flows between UPF network elements.
  • N10 The interface between SMF network element and UDM network element, which can be used by SMF network element to obtain session management related information from UDM network element. Contract data, as well as information related to the SMF network element registering the terminal device session with the UDM.
  • N11 The interface between SMF network element and AMF network element, which can be used to transmit PDU session tunnel information between access network equipment and UPF network element, transmit control messages sent to terminal equipment, transmit wireless resource control information sent to access network equipment, etc.
  • N15 The interface between the PCF network element and the AMF network element, which can be used to issue terminal device policies and access control related policies.
  • N35 The interface between the UDM network element and the UDR network element, which can be used by the UDM network element to obtain user contract data information from the UDR network element.
  • N36 The interface between the PCF network element and the UDR network element, which can be used by the PCF network element to obtain policy-related contract data and application data-related information from the UDR network element.
  • the above network element or function can be a network element in a hardware device, a software function running on dedicated hardware, or a virtualized function instantiated on a platform (e.g., a cloud platform).
  • a platform e.g., a cloud platform
  • the above network element or function can be implemented by one device, or by multiple devices, or a functional module in one device, which is not specifically limited in the embodiments of the present application.
  • FIG4 is a flow chart of a communication method provided in an embodiment of the present application.
  • the flow is also called a registration flow of a network element service.
  • the method comprises the following steps:
  • Step 401 A first network element sends a network element registration request to a network storage network element.
  • the network storage network element receives the network element registration request.
  • the first network element is a NF network element, such as an AMF network element, SMF network element, UPF network element, UDM network element, etc.
  • the network storage network element can be an NRF network element in a 5G system, or it can be a network element having the functions of the above-mentioned NRF network element in future communications such as 6G networks. This application does not limit this.
  • the network element registration request includes network element parameter information of the first network element, and the network element parameter information includes identification information (shared-data-id) of shared data (shared-data) and identification information of the first network element, but does not include the shared data corresponding to the identification information of the shared data.
  • the shared data includes one or more of the same attribute information corresponding to multiple NF network elements.
  • NF network element 1 includes attribute information 1, attribute information 2, and attribute information 3
  • NF network element 1 includes attribute information 1, attribute information 2, and attribute information 4. Since both NF network element 1 and NF network element 2 include attribute information 1 and attribute information 2, attribute information 1 and attribute information 2 can be used as shared data between NF network element 1 and NF network element 2, or attribute information 1 can be used as shared data between NF network element 1 and NF network element 2, or attribute information 2 can be used as shared data between NF network element 1 and NF network element 2.
  • this is an example of two NF network elements sharing data, and the present application is also applicable to the case of sharing data between three or more NF network elements.
  • the shared data includes one or more of the following attribute information:
  • the network element supports providing service area information: such as the list of cells, base stations, or tracking areas (TAs) that the network element supports providing services;
  • service area information such as the list of cells, base stations, or tracking areas (TAs) that the network element supports providing services
  • Network element service list that is, the list of services supported by the current network element and provided to other network elements
  • Network element capability information that is, the extended capability information supported by the network element, such as Vehicle to X (V2X) capability, Proximity Service (ProSe) capability, or a list of IP address segments that support service provision, a list of supported data network names (DNN) and/or single network slice selection assistance information (S-NSSAI) list, etc.
  • V2X Vehicle to X
  • Proximity Service Proximity Service
  • DNN data network names
  • S-NSSAI single network slice selection assistance information
  • Supported user list that is, the list of users whose services are supported by the current network element, such as user number segment list, user group ID list, etc.
  • Step 402 The network storage element stores the element parameter information.
  • the network element parameter information sent by these NF network elements may have many duplicate contents.
  • the network element parameter information sent by each NF network element in the same NF set (NF SET) to the network storage network element except for the NF address information and NF identification, other information (such as the service area information supported by the network element, the network element service list, the network element capability information, and/or the supported user list, etc.) is highly similar.
  • each NF network element no longer sends the same content in the network element parameter information, that is, shared data, that is, does not carry the shared data in the network element parameter information, but carries the identification information of the shared data.
  • the network element parameter information sent does not carry shared data but carries identification information of the shared data, which can reduce the size of the network element parameter information, thereby reducing the bandwidth resource overhead and signaling overhead between the first network element and the network storage network element.
  • the network storage network element determines whether the shared data identification information corresponding to the storage Shared data. If the shared data is not stored, the network storage network element may obtain the shared data and store the shared data. The network storage network element may obtain the shared data by following step 403a or step 403b.
  • Step 403a the network storage element obtains shared data from the central node.
  • the central node may be a UDR network element or other network storage network elements.
  • the central node is a unique central node in a public land mobile network (PLMN), so the network storage network element obtains the shared data corresponding to the identification information of the shared data from the unique central node.
  • PLMN public land mobile network
  • the identification information of the shared data can be PLMN granularity, that is, the identification information of the shared data is unique in the PLMN.
  • the network element registration request in the above step 401 can carry information of the central node, such as the identification, address or uniform resource locator (URL) of the central node, and then the network storage network element obtains the shared data corresponding to the identification information of the shared data from the central node.
  • the information of the central node can be located in the network element parameter information, and can also be carried in the network element registration request in parallel with the network element parameter information.
  • the identification information of the shared data can be the central node granularity, that is, the identification information of the shared data is unique in a central node.
  • central nodes in a PLMN there are two central nodes in a PLMN, namely central node 1 and central node 2, central node 1 stores shared data 1 and shared data 2, central node 2 stores shared data 3 and shared data 4, shared data 1 and shared data 2 are indicated by identification information 1 and identification information 2 respectively, and shared data 3 and shared data 4 are also indicated by identification information 1 and identification information 2 respectively.
  • identification information 1 and identification information 2 there are two identification information 1 and two identification information 2 in one PLMN, but the two identification information 1 indicate different shared data, and the two identification information 2 also indicate different shared data. Therefore, there may be multiple identification information of the same shared data in one PLMN, but there are no two identical identification information of shared data in the same central node.
  • the network storage network element may send a subscription request to the central node, wherein the subscription request includes the identification information of the shared data, and the subscription request is used to subscribe to the updated shared data corresponding to the identification information of the shared data.
  • Step 403b The network storage network element obtains the shared data from the first network element.
  • the network storage network element may send a subscription request to the first network element, wherein the subscription request includes the identification information of the shared data, and the subscription request is used to subscribe to the updated shared data corresponding to the identification information of the shared data.
  • the network storage network element when the network storage network element does not store the shared data corresponding to the identification information of the shared data, the network storage network element obtains the shared data from the central node or the first network element and stores the shared data. In addition, the network storage network element only needs to store one copy of the shared data, which can reduce the occupation of the storage resources of the network storage network element and improve the resource utilization efficiency.
  • the network storage network element determines that the shared data corresponding to the identification information of the shared data has been stored, the network storage network element does not need to obtain the shared data again, that is, for the same shared data, the network storage network element only needs to store one copy, thereby reducing the storage resource occupation of the network storage network element.
  • the shared data stored by the network storage network element may be triggered by a network element registration request sent by another NF network element different from the first network element (hereinafter referred to as NF1 network element) to trigger the network storage network element to obtain, that is, before step 401, the NF1 network element sends a network element registration request to the network storage network element, the network element registration request includes network element parameter information, the network element parameter information includes the identification information of the shared data, and the network storage network element determines that the shared data corresponding to the identification information of the shared data is not stored locally, then obtains the shared data from the central node or the NF1 network element and stores it locally.
  • NF1 network element another NF network element different from the first network element
  • the network storage network element receives the network element registration request from the first network element, it determines that the shared data has been stored locally, and then it does not need to obtain the shared data from the central node or the first network element. It should be noted that, in this case, the network storage network element can send a subscription request to the central node or the NF1 network element.
  • the subscription request includes identification information of the shared data.
  • the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • AMF1, AMF2, and AMF3 register with the network storage network element in turn, and that AMF1, AMF2, and AMF3 correspond to the same shared data.
  • AMF1 registers with the network storage network element, it sends identification information of the shared data.
  • the network storage network element can obtain the shared data corresponding to the identification information of the shared data from AMF1 or the central node. If the network storage network element has not subscribed to the updated shared data corresponding to the identification information of the shared data, it can subscribe to the updated shared data corresponding to the identification information of the shared data from AMF1 or the central node.
  • AMF2 and AMF3 register with the network storage network element, they send identification information of the shared data. If the network storage network element determines that the shared data corresponding to the identification information of the shared data has been stored locally, it is not necessary to obtain the shared data again. And since the updated shared data corresponding to the identification information of the shared data has been subscribed to AMF1 or the central node, there is no need to re-subscribe.
  • AMF1, AMF2, and AMF3 only need to send the shared data when registering with the network storage network element.
  • AMF1, AMF2, and AMF3 sending shared data to the network storage network element respectively when registering with the network storage network element, the amount of information sent can be reduced, thereby reducing bandwidth resource overhead and signaling overhead.
  • the network storage network element does not need to store the same data (i.e., shared data) for AMF1, AMF2, and AMF3 respectively, which can reduce the storage resource usage of the network storage network element.
  • AMF1, AMF2, and AMF3 correspond to the same network element service list, service area information supported by the network element, network element capability information, and supported user number segment list.
  • AMF1, AMF2, and AMF3 do not need to send these information once and have the network storage network element store three copies of the same information. Instead, the network storage network element only needs to store one copy of this information.
  • the network element service list, service area information supported by the network element, network element capability information, and supported user number segment list are the shared information between AMF1, AMF2, and AMF3.
  • different NF network elements can share data according to different sharing levels.
  • the sharing level is used to indicate the granularity of data sharing.
  • the granularity of data sharing indicated by the sharing level can be the granularity of the network element set (NF SET), the granularity of the network or the granularity of the central node, etc. These sharing granularities are introduced below.
  • the first method is to use the sharing level to indicate data sharing at the granularity of a network element set.
  • NF SET1 which includes AMF1, AMF2 and AMF3.
  • shared data 1 the same attribute information between AMF1 and AMF2
  • shared data 2 the same attribute information between AMF2 and AMF3
  • AMF1, AMF2, and AMF3 can all be specific examples of the first network element.
  • AMF1 When AMF1 sends a network element registration request to the network storage network element, it carries the identification information of shared data 1, the identification information of NF SET1 and the sharing level, which is used to indicate data sharing at the granularity of the network element set.
  • the network storage network element determines whether the shared data 1 corresponding to the identification information of NF SET1 and the identification information of shared data 1 is stored locally. If shared data 1 is stored, it is not necessary to obtain shared data 1 from other network elements. If shared data 1 is not stored, shared data 1 can be obtained from the central node or AMF1.
  • AMF2 When AMF2 sends a network element registration request to the network storage network element, it carries the identification information of shared data 1, the identification information of shared data 2, the identification information of NF SET1, and the sharing level, and the sharing level is used to indicate that data sharing is performed at the granularity of the network element set.
  • the network storage network element determines whether the shared data 1 corresponding to the identification information of the NF SET1 and the identification information of shared data 1 is stored locally. If shared data 1 is stored, it is not necessary to obtain shared data 1 from other network elements. If shared data 1 is not stored, shared data 1 can be obtained from the central node or AMF2.
  • the network storage network element determines whether the shared data 2 corresponding to the identification information of the NF SET1 and the identification information of shared data 2 is stored locally. If shared data 2 is stored, it is not necessary to obtain shared data 2 from other network elements. If shared data 2 is not stored, shared data 2 can be obtained from the central node or AMF2.
  • AMF3 When AMF3 sends a network element registration request to the network storage network element, it carries the identification information of shared data 2, the identification information of NF SET1 and the sharing level, which is used to indicate data sharing at the granularity of the network element set.
  • the network storage network element determines whether the shared data 2 corresponding to the identification information of NF SET1 and the identification information of shared data 2 is stored locally. If shared data 2 is stored, there is no need to obtain shared data 2 from other network elements. If shared data 2 is not stored, shared data 2 can be obtained from the central node or AMF3.
  • the second method, sharing level is used to indicate data sharing at the granularity of the network.
  • the network here can be identified by DNN, or by a network slice identifier (ie, S-NSSAI), or by a data network and a network slice identifier.
  • a network slice identifier ie, S-NSSAI
  • DNN+S-NSSAI identification network it is assumed that when SMF1 and SMF2 send network element registration requests to the network storage network element, they both carry the identification information of shared data 1, DNN1, S-NSSAI1 and the sharing level, and the sharing level is used to indicate data sharing at the granularity of the network.
  • the network storage network element determines whether shared data 1 corresponding to the identification information, DNN1 and S-NSSAI1 of shared data 1 is stored locally. If shared data 1 is stored, there is no need to obtain shared data 1 from other network elements. If shared data 1 is not stored, shared data 1 can be obtained from the central node, or from SMF1 or SMF2.
  • SMF1 and SMF2 are specific examples of the first network element mentioned above. SMF1 and SMF2 both correspond to shared data 1.
  • SMF3 and SMF4 send network element registration requests to the network storage network element, they both carry the identification information of shared data 2, DNN1, S-NSSAI2 and the sharing level, where the sharing level is used to indicate data sharing at the granularity of the network.
  • the network storage network element determines whether shared data 2 corresponding to the identification information, DNN1 and S-NSSAI2 of shared data 2 is stored locally. If shared data 2 is stored, there is no need to obtain shared data 2 from other network elements. If shared data 2 is not stored, shared data 2 can be obtained from the central node, or from SMF3 or SMF4.
  • SMF3 and SMF4 are specific examples of the first network element mentioned above. SMF3 and SMF4 both correspond to shared data 2.
  • the third method, sharing level is used to indicate data sharing at the granularity of the central node.
  • SMF1 and SMF2 send a network element registration request to the network storage network element, they both carry the identification information of shared data 1, the central node
  • the identification information and sharing level of point 1 the sharing level is used to indicate that data sharing is performed at the granularity of the central node.
  • the network storage network element determines whether the shared data 1 corresponding to the identification information of the shared data 1 and the identification information of the central node 1 is stored locally. If the shared data 1 is stored, there is no need to obtain the shared data 1 from other network elements. If the shared data 1 is not stored, the shared data 1 can be obtained from the central node 1.
  • SMF1 and SMF2 are specific examples of the first network element mentioned above. Both SMF1 and SMF2 correspond to shared data 1.
  • SMF3 and SMF4 send a network element registration request to a network storage network element, they both carry the identification information of shared data 2, the identification information of central node 2, and the sharing level, where the sharing level is used to indicate data sharing at the granularity of the central node.
  • the network storage network element determines whether shared data 2 corresponding to the identification information of shared data 2 and the identification information of central node 2 is stored locally. If shared data 2 is stored, there is no need to obtain shared data 2 from other network elements. If shared data 2 is not stored, shared data 2 can be obtained from central node 2.
  • SMF3 and SMF4 here are specific examples of the first network element mentioned above. SMF3 and SMF4 both correspond to shared data 2.
  • the information that a certain NF network element needs to register includes information 1, information 2 and information 3.
  • the information 1 is shared with other NF network elements according to the granularity of the network element set
  • the information 2 is shared with other NF network elements according to the granularity of the network
  • the information 3 is shared with other NF network elements according to the granularity of the central node.
  • FIG5 is a flow chart of a communication method provided in an embodiment of the present application.
  • the flow is also called a network element discovery flow.
  • the method can be implemented in combination with the embodiment of FIG4 above, or can be implemented alone, and the present application does not limit it.
  • the method comprises the following steps:
  • Step 501 The second network element sends a network element discovery request to the network storage network element.
  • the network storage network element receives the network element discovery request.
  • the network element discovery request includes the network element type (NF type) and the query condition.
  • the query condition includes, for example, the subscription permanent identifier (SUPI) or capability information of a specific terminal device, indicating a request to the network storage network element to query the NF network element that provides services for the specific terminal device, or to query the NF network element that meets the specified capability information.
  • SUPI subscription permanent identifier
  • Step 502 The network storage network element sends a network element discovery response to the second network element.
  • the second network element receives the network element discovery response.
  • the network storage network element selects the first network element according to the network element type and query conditions in the network element discovery request
  • the network element discovery response includes the identification information of the first network element and the identification information of the shared data, and the identification information of the shared data is used for the second network element to obtain the shared data.
  • the first network element may be the first network element described in the embodiment of FIG4 above.
  • the type of the first network element is the same as the type of the network element in the network element discovery request, and the first network element meets the query condition in the network element discovery request.
  • the network storage network element when the network storage network element returns the queried information of the first network element to the second network element, it does not need to send the shared data corresponding to the first network element to the second network element, but instead sends the identification information of the shared data corresponding to the first network element to the second network element, thereby reducing bandwidth resource overhead and signaling overhead.
  • the second network element determines whether the shared data corresponding to the identification information of the shared data has been stored locally. If the shared data corresponding to the identification information of the shared data has been stored, the second network element does not need to obtain the shared data from other network elements. When the shared data is needed later, it can be obtained locally. If the shared data corresponding to the identification information of the shared data is not stored, the shared data can be obtained from other network elements and stored. For example, the shared data can be obtained by following the steps 503a or 503b.
  • Step 503a The second network element obtains shared data from the network storage network element.
  • the second network element may send a subscription request to the network storage network element, wherein the subscription request includes the identification information of the shared data, and the subscription request is used to subscribe to the updated shared data corresponding to the identification information of the shared data.
  • Step 503b The second network element obtains shared data from the central node.
  • the second network element obtains the shared data from the central node according to the central node information.
  • the network storage network element does not need to store the shared data, and the central node can store the shared data.
  • the second network element may send a subscription request to the central node, wherein the subscription request includes the identification information of the shared data, and the subscription request is used to subscribe to the updated shared data corresponding to the identification information of the shared data.
  • the second network element when the second network element does not store the shared data corresponding to the identification information of the shared data, the second network element obtains the shared data from the central node or the network storage network element and stores the shared data. In addition, the second network element only needs to store one copy of the shared data, which can reduce the storage resource occupation of the second network element and improve resource utilization efficiency.
  • the network storage network element includes hardware structures and/or software modules corresponding to the execution of each function.
  • the present application can be implemented in the form of hardware or a combination of hardware and computer software. Whether a function is executed in the form of hardware or computer software driving hardware depends on the specific application scenario and design constraints of the technical solution.
  • Figures 6 and 7 are schematic diagrams of possible communication devices provided in embodiments of the present application. These communication devices can be used to implement the functions of the network storage network element in the above method embodiments, and thus can also achieve the beneficial effects possessed by the above method embodiments.
  • the communication device can be a network storage network element, or a module (such as a chip) applied to a network storage network element.
  • the communication device 600 shown in Fig. 6 includes a processing unit 610 and a transceiver unit 620.
  • the communication device 600 is used to implement the function of the network storage network element in the method embodiment shown in Fig. 4 or Fig. 5 above.
  • the transceiver unit 620 is used to receive a network element registration request from a first network element, the network element registration request includes network element parameter information of the first network element, the network element parameter information includes identification information of shared data and identification information of the first network element, and the network element parameter information does not include the shared data corresponding to the identification information of the shared data; the processing unit 610 is used to store the network element parameter information.
  • the communication device 600 has stored the shared data.
  • the transceiver unit 620 is further used to send a subscription request to the central node, where the subscription request includes the identification information of the shared data, and the subscription request is used to subscribe to the updated shared data corresponding to the identification information of the shared data.
  • the processing unit 610 is further configured to obtain the shared data and store the shared data.
  • the processing unit 610 is specifically configured to obtain the shared data from the first network element.
  • the transceiver unit 620 is further used to send a subscription request to the first network element, where the subscription request includes identification information of the shared data, and the subscription request is used to subscribe to updated shared data corresponding to the identification information of the shared data.
  • the registration request also includes information of a central node; the processing unit 610 is specifically configured to obtain the shared data from the central node.
  • the transceiver unit 620 is further used to send a subscription request to the central node, where the subscription request includes the identification information of the shared data, and the subscription request is used to subscribe to the updated shared data corresponding to the identification information of the shared data.
  • the registration request further includes a sharing level, where the sharing level is used to indicate the granularity of data sharing.
  • the registration request also includes identification information of the first network element set to which the first network element belongs, and the sharing level is specifically used to indicate data sharing at the granularity of the network element set; the shared data stored by the communication device 600 corresponds to the identification information of the first network element set and the identification information of the shared data.
  • the registration request also includes identification information of the network corresponding to the first network element, and the sharing level is specifically used to indicate data sharing at a network granularity, and the identification information of the network includes a data network name and/or a network slice identifier; the shared data stored in the communication device 600 corresponds to the identification information of the network and the identification information of the shared data.
  • the registration request also includes information of the central node, and the sharing level is specifically used to indicate data sharing at the granularity of the central node; the shared data stored in the communication device 600 corresponds to the information of the central node and the identification information of the shared data.
  • the transceiver unit 620 is also used to receive a network element discovery request from a second network element, which includes a network element type and a query condition; send a network element discovery response to the second network element, which includes identification information of the first network element and identification information of the shared data, and the identification information of the shared data is used for the second network element to obtain the shared data; wherein the type of the first network element is the same as the type of the network element, and the first network element meets the query condition.
  • the network element discovery response also includes information of a central node, and the information of the central node is used by the second network element to obtain the shared data from the central node.
  • processing unit 610 and the transceiver unit 620 can be directly obtained by referring to the relevant description in the method embodiment shown in FIG. 4 or 5 , and will not be repeated here.
  • the communication device 700 shown in FIG7 includes a processor 710 and an interface circuit 720.
  • the processor 710 and the interface circuit 720 are coupled to each other. It is understood that the interface circuit 720 can be a transceiver or an input-output interface.
  • the communication device 700 may also include a memory 730 for storing instructions executed by the processor 710 or storing input data required by the processor 710 to execute instructions or storing data generated after the processor 710 executes instructions.
  • the processor 710 is used to implement the function of the processing unit 610
  • the interface circuit 720 is used to implement the function of the transceiver unit 620 .
  • the processor in the embodiments of the present application may be a central processing unit (CPU), or other general-purpose processors, digital signal processors (DSP), application specific integrated circuits (ASIC), field programmable gate arrays (FPGA) or other programmable logic devices, transistor logic devices, hardware components or any combination thereof.
  • the general-purpose processor may be a microprocessor or any conventional processor.
  • the method steps in the embodiments of the present application can be implemented by hardware, or by a processor executing software instructions.
  • the software instructions can be composed of corresponding software modules, and the software modules can be stored in a random access memory, a flash memory, a read-only memory, a programmable read-only memory, an erasable programmable read-only memory, an electrically erasable programmable read-only memory, a register, a hard disk, a mobile hard disk, a CD-ROM, or any other form of storage medium well known in the art.
  • An exemplary storage medium is coupled to the processor so that the processor can read information from the storage medium and can write information to the storage medium.
  • the storage medium can also be a component of the processor.
  • the processor and the storage medium can be located in an ASIC.
  • the ASIC can be located in a base station or a terminal device.
  • the processor and the storage medium can also be present in a base station or a terminal device as discrete components.
  • the computer program product includes one or more computer programs or instructions.
  • the computer may be a general-purpose computer, a special-purpose computer, a computer network, a base station, a user device or other programmable device.
  • the computer program or instruction may be stored in a computer-readable storage medium, or transmitted from one computer-readable storage medium to another computer-readable storage medium, for example, the computer program or instruction may be transmitted from one website site, computer, server or data center to another website site, computer, server or data center by wired or wireless means.
  • the computer-readable storage medium may be any available medium that a computer can access or a data storage device such as a server, data center, etc. that integrates one or more available media.
  • the available medium may be a magnetic medium, for example, a floppy disk, a hard disk, a tape; it may also be an optical medium, for example, a digital video disc; it may also be a semiconductor medium, for example, a solid-state hard disk.
  • the computer-readable storage medium may be a volatile or nonvolatile storage medium, or may include both volatile and nonvolatile types of storage media.
  • “at least one” means one or more, and “more than one” means two or more.
  • “And/or” describes the association relationship of associated objects, indicating that three relationships may exist.
  • a and/or B can mean: A exists alone, A and B exist at the same time, and B exists alone, where A and B can be singular or plural.
  • the character “/” generally indicates that the previous and next associated objects are in an “or” relationship; in the formula of this application, the character “/” indicates that the previous and next associated objects are in a "division” relationship.

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Abstract

本申请提供一种通信方法、通信装置及通信系统。该方法包括:网络存储网元接收来自第一网元的网元注册请求,该网元注册请求中包括该第一网元的网元参数信息,该网元参数信息包括共享数据的标识信息和该第一网元的标识信息,该网元参数信息中不包括该共享数据的标识信息对应的该共享数据;该网络存储网元存储该网元参数信息。该方案,第一网元向网络存储网元进行服务注册时,发送的网元参数信息中不携带共享数据,而是携带共享数据的标识信息,可以减少网元参数信息的大小,从而减少第一网元与网络存储网元之间的带宽资源开销和信令开销。

Description

通信方法、通信装置及通信系统
相关申请的交叉引用
本申请要求在2022年10月13日提交中国专利局、申请号为202211253976.0、申请名称为“通信方法、通信装置及通信系统”的中国专利申请的优先权,其全部内容通过引用结合在本申请中。
技术领域
本申请涉及无线通信技术领域,尤其涉及通信方法、通信装置及通信系统。
背景技术
第五代(5th generation,5G)网络架构中,为了实现网元服务的注册流程,引入了网络存储功能(network repository function,NRF)网元,该流程如下:网络功能(network function,NF)网元向NRF网元发送网元注册请求,该网元注册请求包括网元参数信息(NFprofile),然后NRF存储该网元参数信息。
当多个NF网元向NRF网元进行注册,如果携带的网元参数信息中的内容较多,将会造成NF网元与NRF网元之间的带宽资源开销和信令开销较大。
发明内容
本申请提供通信方法、通信装置及通信系统,用以实现减少网络存储网元的带宽资源开销和信令开销。
第一方面,本申请实施例提供一种通信方法,该方法可以由网络存储网元或应用于网络存储网元的芯片来执行。以网络存储网元执行该方法为例,网络存储网元接收来自第一网元的网元注册请求,该网元注册请求中包括该第一网元的网元参数信息,该网元参数信息包括共享数据的标识信息和该第一网元的标识信息,该网元参数信息中不包括该共享数据的标识信息对应的该共享数据;该网络存储网元存储该网元参数信息。
上述方案,第一网元向网络存储网元进行服务注册时,发送的网元参数信息中不携带共享数据,而是携带共享数据的标识信息,可以减少网元参数信息的大小,从而减少第一网元与网络存储网元之间的带宽资源开销和信令开销。
一种可能的实现方法中,该网络存储网元已存储有该共享数据。
上述方案,网络存储网元只需要存储一份该共享数据,可以减少对网络存储网元的存储资源的占用,提高了资源利用效率。
一种可能的实现方法中,该网络存储网元向中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
上述方案,通过订阅更新的共享数据,可以保障网络存储网元存储最新的共享数据,有利于其它网元从网络存储网元获取到正确的数据。
一种可能的实现方法中,该网络存储网元获取该共享数据,并存储该共享数据。
上述方案,当网络存储网元没有存储与共享数据的标识信息对应的共享数据时,该网络存储网元获取该共享数据并存储该共享数据,并且网络存储网元只需要存储一份该共享数据,可以减少对网络存储网元的存储资源的占用,提高了资源利用效率。
一种可能的实现方法中,该网络存储网元从该第一网元获取该共享数据。
一种可能的实现方法中,该网络存储网元向该第一网元发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
上述方案,通过订阅更新的共享数据,可以保障网络存储网元存储最新的共享数据,有利于其它网元从网络存储网元获取到正确的数据。
一种可能的实现方法中,该注册请求还包括中心节点的信息;该网络存储网元从该中心节点获取该共享数据。
一种可能的实现方法中,该网络存储网元向该中心节点发送订阅请求,该订阅请求中包括该共享数 据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
上述方案,通过订阅更新的共享数据,可以保障网络存储网元存储最新的共享数据,有利于其它网元从网络存储网元获取到正确的数据。
一种可能的实现方法中,该注册请求还包括共享等级,该共享等级用于指示进行数据共享的粒度。
上述方案,按照共享等级进行数据共享,有助于实现数据共享方式的灵活性。
一种可能的实现方法中,该注册请求还包括该第一网元归属的第一网元集合的标识信息,该共享等级具体用于指示以网元集合的粒度进行数据共享;该网络存储网元存储的该共享数据对应该第一网元集合的标识信息和该共享数据的标识信息。
一种可能的实现方法中,该注册请求还包括该第一网元对应的网络的标识信息,该共享等级具体用于指示以网络的粒度进行数据共享,该网络的标识信息包括数据网络名称和/或网络切片标识;该网络存储网元存储的该共享数据对应该网络的标识信息和该共享数据的标识信息。
一种可能的实现方法中,该注册请求还包括中心节点的信息,该共享等级具体用于指示以中心节点的粒度进行数据共享;该网络存储网元存储的该共享数据对应该中心节点的信息和该共享数据的标识信息。
一种可能的实现方法中,该网络存储网元接收来自第二网元的网元发现请求,该网元发现请求中包括网元类型和查询条件;该网络存储网元向该第二网元发送网元发现响应,该网元发现响应包括该第一网元的标识信息和该共享数据的标识信息,该共享数据的标识信息用于该第二网元获取该共享数据;其中,该第一网元的类型与该网元类型相同,该第一网元满足该查询条件。
上述方案,网络存储网元向第二网元返回查询到的第一网元的信息时,不需要将第一网元对应的共享数据发送给第二网元,而是将第一网元对应的共享数据的标识信息发送给第二网元,从而可以减少带宽资源开销和信令开销。
一种可能的实现方法中,该网元发现响应还包括中心节点的信息,该中心节点的信息用于该第二网元向该中心节点获取该共享数据。
上述方案,第二网元可以向中心节点获取共享数据,而不向数据存储网元获取共享数据,因此数据存储网元可以不需要存储该共享数据,可以减少数据存储网元的存储资源的占用。
第二方面,本申请实施例提供一种通信装置,该装置可以是网络存储网元,还可以是用于网络存储网元的芯片。该装置具有实现上述第一方面的任意实现方法的功能。该功能可以通过硬件实现,也可以通过硬件执行相应的软件实现。该硬件或软件包括一个或多个与上述功能相对应的模块。
第三方面,本申请实施例提供一种通信装置,包括与存储器耦合的处理器,该处理器用于调用所述存储器中存储的程序,以执行上述第一方面中的任意实现方法。该存储器可以位于该装置之内,也可以位于该装置之外。且该处理器可以是一个或多个。
第四方面,本申请实施例提供一种通信装置,包括处理器和存储器;该存储器用于存储计算机指令,当该装置运行时,该处理器执行该存储器存储的计算机指令,以使该装置执行上述第一方面中的任意实现方法。
第五方面,本申请实施例提供一种通信装置,包括用于执行上述第一方面中的任意实现方法的各个步骤的单元或手段(means)。
第六方面,本申请实施例提供一种通信装置,包括处理器和接口电路,所述处理器用于通过接口电路与其它装置通信,并执行上述第一方面中的任意实现方法。该处理器包括一个或多个。
第七方面,本申请实施例还提供一种计算机可读存储介质,所述计算机可读存储介质中存储有指令,当其在通信装置上运行时,使得上述第一方面中的任意实现方法被执行。
第八方面,本申请实施例还提供一种计算机程序产品,该计算机程序产品包括计算机程序或指令,当计算机程序或指令被通信装置运行时,使得上述第一方面中的任意实现方法被执行。
第九方面,本申请实施例还提供一种芯片系统,包括:处理器,用于执行上述第一方面中的任意实现方法。
第十方面,本申请实施例还提供了一种通信系统,该通信系统包括用于执行上述第一方面任意实现方法的网络存储网元,和用于向该网络存储网元发送网元注册请求的第一网元。
第十一方面,本申请实施例还提供了一种通信方法,第一网元发送网元注册请求给网络存储网元,该网元注册请求中包括该第一网元的网元参数信息,该网元参数信息中包括共享数据的标识信息和该第 一网元的标识信息,该网元参数信息中不包括该共享数据的标识信息对应的该共享数据;该网络存储网元存接收第一网元发送的网元注册请求,存储该网元注册请求携带的网元参数信息。
在具体实现中,该网络存储网元可以执行上述第一方面任意实现方法。
附图说明
图1为本申请实施例提供的一种通信系统示意图;
图2为基于服务化架构的5G网络架构示意图;
图3为基于点对点接口的5G网络架构示意图;
图4为本申请实施例提供的一种通信方法的流程示意图;
图5为本申请实施例提供的一种通信方法的流程示意图;
图6为本申请实施例提供的一种通信装置示意图;
图7为本申请实施例提供的一种通信装置示意图。
具体实施方式
为减少网络存储网元的带宽资源开销和信令开销,本申请提供一种通信系统,参考图1,该系统包括网络存储网元和第一网元,可选的,该通信系统还包括第二网元。
图1所示的系统可以用在图2或图3所示的5G网络架构中,当然,也可以用在未来网络架构,比如第六代(6th generation,6G)网络架构等,本申请不做限定。
图1中的网络存储网元可以是图2或图3中的NRF网元,也可以是未来通信如6G通信中的具有NRF网元的功能的网元,本申请对此不做限定。
图1中的第一网元是NF网元,比如可以是图2或图3中的AMF网元、SMF网元、UPF网元或UDM网元等,也可以是未来通信如6G通信中的具有AMF网元、SMF网元、UPF网元或UDM网元等的功能的网元,本申请对此不做限定。
图1中的第二网元NF网元,比如可以是图2或图3中的AMF网元、SMF网元、UPF网元或UDM网元等,也可以是未来通信如6G通信中的具有AMF网元、SMF网元、UPF网元或UDM网元等的功能的网元,本申请对此不做限定。
第一网元,用于向网络存储网元发送网元注册请求,该网元注册请求中包括该第一网元的网元参数信息,该网元参数信息包括共享数据的标识信息和该第一网元的标识信息,该网元参数信息中不包括该共享数据的标识信息对应的该共享数据;网络存储网元,用于存储该网元参数信息。
一种可能的实现方法中,该网络存储网元已存储有该共享数据。
一种可能的实现方法中,该网络存储网元,还用于向中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
一种可能的实现方法中,该网络存储网元,还用于获取该共享数据,并存储该共享数据。
一种可能的实现方法中,该网络存储网元,具体用于从该第一网元获取该共享数据。
一种可能的实现方法中,该网络存储网元,还用于向该第一网元发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
一种可能的实现方法中,该注册请求还包括中心节点的信息;该网络存储网元,具体用于从该中心节点获取该共享数据。
一种可能的实现方法中,该网络存储网元,还用于向该中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
一种可能的实现方法中,该注册请求还包括共享等级,该共享等级用于指示进行数据共享的粒度。
一种可能的实现方法中,该注册请求还包括该第一网元归属的第一网元集合的标识信息,该共享等级具体用于指示以网元集合的粒度进行数据共享;该网络存储网元存储的该共享数据对应该第一网元集合的标识信息和该共享数据的标识信息。
一种可能的实现方法中,该注册请求还包括该第一网元对应的网络的标识信息,该共享等级具体用于指示以网络的粒度进行数据共享,该网络的标识信息包括数据网络名称和/或网络切片标识;该网络存储网元存储的该共享数据对应该网络的标识信息和该共享数据的标识信息。
一种可能的实现方法中,该注册请求还包括中心节点的信息,该共享等级具体用于指示以中心节点 的粒度进行数据共享;该网络存储网元存储的该共享数据对应该中心节点的信息和该共享数据的标识信息。
一种可能的实现方法中,第二网元,用于向网络存储网元发送网元发现请求,该网元发现请求中包括网元类型和查询条件;网络存储网元,还用于向该第二网元发送网元发现响应,该网元发现响应包括该第一网元的标识信息和该共享数据的标识信息,该共享数据的标识信息用于该第二网元获取该共享数据;其中,该第一网元的类型与该网元类型相同,该第一网元满足该查询条件。
一种可能的实现方法中,该网元发现响应还包括中心节点的信息,该中心节点的信息用于该第二网元向该中心节点获取该共享数据。
系统中各个网元之间的交互,以及具体的执行,可以参考下面方法实施例,这里不再赘述。为了应对无线宽带技术的挑战,保持第三代合作伙伴计划(3rd generation partnership project,3GPP)网络的领先优势,3GPP标准组制定了下一代移动通信网络系统(Next Generation System)架构,称为5G网络架构。该架构不但支持3GPP标准组定义的无线接入技术(如长期演进(long term evolution,LTE)接入技术,5G无线接入网(radio access network,RAN)接入技术等)接入到5G核心网(core network,CN),而且支持使用非3GPP(non-3GPP)接入技术通过非3GPP转换功能(non-3GPP interworking function,N3IWF)或下一代接入网关(next generation packet data gateway,ngPDG)接入到核心网。
图2为基于服务化架构的5G网络架构示意图。图2所示的5G网络架构中可包括接入网设备以及核心网设备。终端设备通过接入网设备和核心网设备接入数据网络(data network,DN)。其中,核心网设备包括但不限于以下网元中的部分或者全部:鉴权服务器功能(authentication server function,AUSF)网元(图中未示出)、统一数据管理(unified data management,UDM)网元、统一数据库(unified data repository,UDR)网元、NRF网元(图中未示出)、网络开放功能(network exposure function,NEF)网元(图中未示出)、应用功能(application function,AF)网元、策略控制功能(policy control function,PCF)网元、接入与移动性管理功能(access and mobility management function,AMF)网元、会话管理功能(session management function,SMF)网元、用户面功能(user plane function,UPF)网元、绑定支持功能(binding support function,BSF)网元(图中未示出)。
终端设备可以是用户设备(user equipment,UE)、移动台、移动终端设备等。终端设备可以广泛应用于各种场景,例如,设备到设备(device-to-device,D2D)、车物(vehicle to everything,V2X)通信、机器类通信(machine-type communication,MTC)、物联网(internet of things,IOT)、虚拟现实、增强现实、工业控制、自动驾驶、远程医疗、智能电网、智能家具、智能办公、智能穿戴、智能交通、智慧城市等。终端设备可以是手机、平板电脑、带无线收发功能的电脑、可穿戴设备、车辆、城市空中交通工具(如无人驾驶机、直升机等)、轮船、机器人、机械臂、智能家居设备等。
接入网设备可以是无线接入网设备(RAN设备)或有线接入网设备。其中,无线接入网设备包括3GPP接入网设备、非可信非3GPP接入网设备和可信非3GPP接入网设备。3GPP接入网设备包括但不限于:LTE中的演进型基站(evolved NodeB,eNodeB)、5G移动通信系统中的下一代基站(next generation NodeB,gNB)、未来移动通信系统中的基站或完成基站部分功能的模块或单元,如集中式单元(central unit,CU),分布式单元(distributed unit,DU)等。非可信非3GPP接入网设备包括但不限于:非可信非3GPP接入网关或N3IWF设备、非可信无线局域网(wireless local area network,WLAN)接入点(access point,AP)、交换机、路由器。可信非3GPP接入网设备包括但不限于:可信非3GPP接入网关、可信WLAN AP、交换机、路由器。有线接入网设备包括但不限于:有线接入网关(wireline access gateway)、固定电话网络设备、交换机、路由器。
接入网设备和终端设备可以是固定位置的,也可以是可移动的。接入网设备和终端设备可以部署在陆地上,包括室内或室外、手持或车载;也可以部署在水面上;还可以部署在空中的飞机、气球和人造卫星上。本申请的实施例对接入网设备和终端设备的应用场景不做限定。
AMF网元,包含执行移动性管理、或接入鉴权/授权等功能。此外,还负责在终端设备与PCF间传递用户策略。
SMF网元,包含执行会话管理、执行PCF网元下发的控制策略、选择UPF网元、或分配终端设备的互联网协议(internet protocol,IP)地址等功能。
UPF网元,包含完成用户面数据转发、基于会话/流级的计费统计、或带宽限制等功能。
UDM网元,包含执行管理签约数据、或用户接入授权等功能。
UDR,包含执行签约数据、策略数据、或应用数据等类型数据的存取功能。
NEF网元,用于支持能力和事件的开放。
AF网元,传递应用侧对网络侧的需求,例如,QoS需求或用户状态事件订阅等。AF可以是第三方功能实体,也可以是运营商部署的应用服务,如IP多媒体子系统(IP Multimedia Subsystem,IMS)语音呼叫业务。其中,AF网元包括核心网内的AF网元(即运营商的AF网元)和第三方AF网元(如某个企业的应用服务器)。
PCF网元,包含负责针对会话、业务流级别进行计费、QoS带宽保障及移动性管理、或终端设备策略决策等策略控制功能。PCF网元包括接入与移动性管理策略控制网元(access and mobility management policy control function,AM PCF)网元和会话管理策略控制功能(session management PCF,SM PCF)网元。其中,AM PCF网元用于为终端设备制定AM策略和用户策略,AM PCF网元也可以称为为终端设备提供服务的策略控制网元(PCF for a UE))。SM PCF网元用于为会话制定会话管理策略(session management policy,SM策略),SM PCF网元也可以称为为协议数据单元(protocol data unit,PDU)会话提供服务的策略控制网元((PCF for a PDU session))。
NRF网元,可用于提供网元发现功能,基于其他网元的请求,提供网元类型对应的网元信息。NRF网元还提供网元管理服务,如网元注册、更新、去注册、或网元状态订阅和推送等。
BSF网元,可提供BSF服务注册/注销/更新,与NRF网元连接检测,会话绑定信息创建,终端设备信息的获取,IP地址重复的会话绑定信息查询等功能。
AUSF网元,负责对用户进行鉴权,以确定是否允许用户或设备接入网络。
DN,是位于运营商网络之外的网络,运营商网络可以接入多个DN,DN上可部署多种业务,可为终端设备提供数据和/或语音等服务。例如,DN是某智能工厂的私有网络,智能工厂安装在车间的传感器可为终端设备,DN中部署了传感器的控制服务器,控制服务器可为传感器提供服务。传感器可与控制服务器通信,获取控制服务器的指令,根据指令将采集的传感器数据传送给控制服务器等。又例如,DN是某公司的内部办公网络,该公司员工的手机或者电脑可为终端设备,员工的手机或者电脑可以访问公司内部办公网络上的信息、数据资源等。
图2中Npcf、Nudr、Nudm、Naf、Namf、Nsmf分别为上述PCF、UDR、UDM、AF、AMF和SMF提供的服务化接口,用于调用相应的服务化操作。N1、N2、N3、N4以及N6为接口序列号,这些接口序列号的含义如下:
1)、N1:AMF网元与终端设备之间的接口,可以用于向终端设备传递非接入层(non access stratum,NAS)信令(如包括来自AMF网元的QoS规则)等。
2)、N2:AMF网元与接入网设备之间的接口,可以用于传递核心网侧至接入网设备的无线承载控制信息等。
3)、N3:接入网设备与UPF网元之间的接口,主要用于传递接入网设备与UPF网元间的上下行用户面数据。
4)、N4:SMF网元与UPF网元之间的接口,可以用于控制面与用户面之间传递信息,包括控制面向用户面的转发规则、QoS规则、流量统计规则等的下发以及用户面的信息上报。
5)、N6:UPF网元与DN的接口,用于传递UPF网元与DN之间的上下行用户数据流。
图3为基于点对点接口的5G网络架构示意图,其中的网元的功能的介绍可以参考图2中对应的网元的功能的介绍,不再赘述。图3与图2的主要区别在于:图2中的各个控制面网元之间的接口是服务化的接口,图3中的各个控制面网元之间的接口是点对点的接口。
在图3所示的架构中,各个网元之间的接口名称及功能如下:
1)、N1、N2、N3、N4和N6接口的含义可以参考前述描述。
2)、N5:AF网元与PCF网元之间的接口,可以用于应用业务请求下发以及网络事件上报。
3)、N7:PCF网元与SMF网元之间的接口,可以用于下发PDU会话粒度以及业务数据流粒度控制策略。
4)、N8:AMF网元与UDM网元间的接口,可以用于AMF网元向UDM网元获取接入与移动性管理相关签约数据与鉴权数据,以及AMF向UDM注册终端设备移动性管理相关信息等。
5)、N9:UPF网元和UPF网元之间的用户面接口,用于传递UPF网元间的上下行用户数据流。
6)、N10:SMF网元与UDM网元间的接口,可以用于SMF网元向UDM网元获取会话管理相关 签约数据,以及SMF网元向UDM注册终端设备会话相关信息等。
7)、N11:SMF网元与AMF网元之间的接口,可以用于传递接入网设备和UPF网元之间的PDU会话隧道信息、传递发送给终端设备的控制消息、传递发送给接入网设备的无线资源控制信息等。
8)、N15:PCF网元与AMF网元之间的接口,可以用于下发终端设备策略及接入控制相关策略。
9)、N35:UDM网元与UDR网元间的接口,可以用于UDM网元从UDR网元中获取用户签约数据信息。
10)、N36:PCF网元与UDR网元间的接口,可以用于PCF网元从UDR网元中获取策略相关签约数据以及应用数据相关信息。
可以理解的是,上述网元或者功能既可以是硬件设备中的网络元件,也可以是在专用硬件上运行软件功能,或者是平台(例如,云平台)上实例化的虚拟化功能。可选的,上述网元或者功能可以由一个设备实现,也可以由多个设备共同实现,还可以是一个设备内的一个功能模块,本申请实施例对此不作具体限定。
图4为本申请实施例提供的一种通信方法的流程示意图。该流程也称为网元服务的注册流程。该方法包括以下步骤:
步骤401,第一网元向网络存储网元发送网元注册请求。相应地,网络存储网元接收该网元注册请求。
该第一网元是一个NF网元,比如是AMF网元、SMF网元、UPF网元、UDM网元等等。
该网络存储网元可以是5G系统中的NRF网元,也可以是未来通信如6G网络中具有上述NRF网元的功能的网元,本申请对此不限定。
该网元注册请求中包括第一网元的网元参数信息,该网元参数信息中包括共享数据(shared-data)的标识信息(shared-data-id)和第一网元的标识信息,但不包括该共享数据的标识信息对应的该共享数据。
其中,该共享数据包括多个NF网元对应的相同属性信息中的一个或多个。示例性地,NF网元1包括属性信息1、属性信息2和属性信息3,NF网元1包括属性信息1、属性信息2和属性信息4,由于NF网元1和NF网元2都包括属性信息1和属性信息2,因此属性信息1和属性信息2可以作为NF网元1与NF网元2之间的共享数据,或者属性信息1作为NF网元1与NF网元2之间的共享数据,或者属性信息2作为NF网元1与NF网元2之间的共享数据。当然,这里是以两个NF网元共享数据为例,本申请也适用于三个或三个以上的NF网元之间共享数据的情形。
一种实现方法中,共享数据包括以下属性信息中的一项或多项:
1)、网元支持提供服务区信息:如网元支持提供服务的小区、基站、或跟踪区域(tracking area,TA)列表等信息;
2)、网元服务列表:即当前网元所支持向其他网元提供的服务列表;
3)、网元能力信息:即网元所支持的扩展能力信息,如车联网(Vehicleto X,V2X)能力、近场通信(Proximity Service,ProSe)能力等,或是支持提供服务的IP地址段列表、支持的数据网络名称(data network name,DNN)和/或单网络切片选择辅助信息(single network slice selection assistance information,S-NSSAI)列表等;
4)、支持的用户列表:即当前网元支持服务的用户列表,如用户号段列表、用户群组标识列表等。
步骤402,网络存储网元存储该网元参数信息。
在NF网元的服务注册流程中,当有多个NF网元向网络存储网元注册,这些NF网元所发送的网元参数信息中的内容可能有很多是重复的,例如同一个NF集合(NF SET)中的各个NF网元向网络存储网元所发送的网元参数信息中,除了NF地址信息、NF标识不同,其他信息(如网元支持的服务区信息、网元服务列表、网元能力信息、和/或支持的用户列表等)高度趋同。本申请中,各个NF网元在注册时,对于网元参数信息中的相同内容,即共享数据,不再发送,也即不在网元参数信息中携带共享数据,而是携带共享数据的标识信息。
上述方案,第一网元向网络存储网元进行服务注册时,发送的网元参数信息中不携带共享数据,而是携带共享数据的标识信息,可以减少网元参数信息的大小,从而减少第一网元与网络存储网元之间的带宽资源开销和信令开销。
一种实现方法中,在上述步骤402之后,网络存储网元判断是否存储有共享数据的标识信息对应的 共享数据。如果未存储共享数据,则网络存储网元可以获取共享数据并存储该共享数据。其中,网络存储网元可以通过以下步骤403a或步骤403b获取共享数据。
步骤403a,网络存储网元从中心节点(central node)获取共享数据。
该中心节点可以是UDR网元或者其它网络存储网元。
一种实现方法中,该中心节点是一个公共陆地移动网络(public land mobile network,PLMN)内唯一的中心节点,因此网络存储网元从该唯一的中心节点获取与共享数据的标识信息对应的共享数据。该情形下,共享数据的标识信息可以是PLMN粒度,也即共享数据的标识信息在PLMN内唯一。
又一种实现方法中,一个PLMN内有多个中心节点,则上述步骤401的网元注册请求中可以携带中心节点的信息,如中心节点的标识、地址或统一资源定位符(uniform resource locator,URL)等信息,然后网络存储网元从该中心节点获取与共享数据的标识信息对应的共享数据。其中,该中心节点的信息可以是位于网元参数信息中,也可以与网元参数信息并列携带于网元注册请求中。该情形下,共享数据的标识信息可以是中心节点粒度,也即共享数据的标识信息在一个中心节点内唯一。例如,一个PLMN内存在2个中心节点,分别为中心节点1和中心节点2,中心节点1存储有共享数据1、共享数据2,中心节点2存储有共享数据3、共享数据4,共享数据1和共享数据2分别用标识信息1和标识信息2进行指示,共享数据3和共享数据4也分别用标识信息1和标识信息2进行指示。可以看出,在一个PLMN内存在两个标识信息1和两个标识信息2,但这两个标识信息1指示不同的共享数据,这两个标识信息2也指示不同的共享数据。因此在一个PLMN内可能存在多个相同的共享数据的标识信息,但在同一个中心节点内,不存在相同的两个共享数据的标识信息。
一种实现方法中,如果网络存储网元之前没有订阅过该共享数据的标识信息对应的更新的共享数据,则在步骤403a之后,网络存储网元可以向中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,订阅请求用于订阅共享数据的标识信息对应的更新的共享数据。
步骤403b,网络存储网元从第一网元获取共享数据。
一种实现方法中,如果网络存储网元之前没有订阅过该共享数据的标识信息对应的更新的共享数据,则在步骤403b之后,网络存储网元可以向第一网元发送订阅请求,该订阅请求中包括该共享数据的标识信息,订阅请求用于订阅共享数据的标识信息对应的更新的共享数据。
上述方案,在网络存储网元中没有存储共享数据的标识信息对应的共享数据的情况下,网络存储网元从中心节点或第一网元获取共享数据并存储该共享数据。并且网络存储网元只需要存储一份该共享数据,可以减少对网络存储网元的存储资源的占用,提高了资源利用效率。
一种实现方法中,在上述步骤402之后,网络存储网元如果确定已经存储有共享数据的标识信息对应的共享数据,则网络存储网元不需要再去获取共享数据,也即对于同一份共享数据,网络存储网元只需要存储一份即可,从而可以减少网络存储网元的存储资源的占用。其中,网络存储网元存储的该共享数据,可以是与第一网元不同的另一个NF网元(以下称为NF1网元)发送的网元注册请求触发网络存储网元进行获取的,也即在步骤401之前,该NF1网元向网络存储网元发送网元注册请求,该网元注册请求中包括网元参数信息,该网元参数信息包括该共享数据的标识信息,网络存储网元确定本地没有存储该共享数据的标识信息对应的共享数据,则从中心节点或该NF1网元获取共享数据并存储在本地。后续当网络存储网元收到来自第一网元的网元注册请求后,确定本地已经存储有共享数据,则不需要再从中心节点或第一网元获取共享数据。需要说明的是,针对该情形,网络存储网元可以向中心节点或该NF1网元发送订阅请求,该订阅请求中包括共享数据的标识信息,订阅请求用于订阅共享数据的标识信息对应的更新的共享数据。
下面结合一个具体示例,对上述方案进行说明。假设AMF1、AMF2、AMF3依次向网络存储网元进行注册,该AMF1、AMF2和AMF3对应相同的共享数据。AMF1向网络存储网元注册时,发送共享数据的标识信息,假设网络存储网元上没有存储该共享数据,则网络存储网元可以从AMF1或中心节点获取该共享数据的标识信息对应的共享数据。如果网络存储网元没有订阅过该共享数据的标识信息对应的更新的共享数据,则可以向AMF1或中心节点订阅该共享数据的标识信息对应的更新的共享数据。后续,当AMF2、AMF3向网络存储网元注册时,发送共享数据的标识信息,网络存储网元确定本地已经存储有该共享数据的标识信息对应的共享数据,则不需要再获取该共享数据。并且由于已经向AMF1或中心节点订阅该共享数据的标识信息对应的更新的共享数据,因此不需要再重新订阅。
可以看出,该示例中,AMF1、AMF2、AMF3在向网络存储网元进行注册时,只需要发送共享数 据的标识信息,不需要发送共享数据的标识信息对应的共享数据。相较于AMF1、AMF2、AMF3向网络存储网元进行注册时分别向网络存储网元发送共享数据,可以减少发送的信息量,因而可以减少带宽资源开销和信令开销。
并且,网络存储网元也不需要为AMF1、AMF2、AMF3分别存储那些相同的数据(即共享数据),可以减少网络存储网元的存储资源的占用。例如,AMF1、AMF2、AMF3对应相同的网元服务列表、网元支持的服务区信息、网元能力信息以及支持的用户号段列表,AMF1、AMF2、AMF3不需要均发送一次这些信息并由网络存储网元存储3份相同的这些信息,而只需要网络存储网元存储一份这些信息即可。网元服务列表、网元支持的服务区信息、网元能力信息以及支持的用户号段列表,即为AMF1、AMF2、AMF3之间的共享信息。
一种实现方法中,本申请实施中,不同的NF网元之间可以按照不同的共享等级进行数据共享,该共享等级用于指示进行数据共享的粒度,该共享等级指示的数据共享的粒度可以是网元集合(NF SET)的粒度、网络的粒度或中心节点的粒度,等等。下面分别对这几种共享粒度进行介绍。
第一种方法,共享等级用于指示以网元集合的粒度进行数据共享
比如存在一个NF SET1,该NF SET1中包括AMF1、AMF2和AMF3。AMF1和AMF2之间相同的属性信息,称为共享数据1,AMF2和AMF3之间相同的属性信息,称为共享数据2。AMF1、AMF2、AMF3均可以是上述第一网元的具体示例。
AMF1向网络存储网元发送网元注册请求时,携带共享数据1的标识信息、NF SET1的标识信息和共享等级,该共享等级用于指示以网元集合的粒度进行数据共享。网络存储网元判断本地是否存储有与该NF SET1的标识信息及共享数据1的标识信息对应的共享数据1。如果存储有共享数据1,则不需要再从其它网元获取共享数据1。如果没有存储共享数据1,则可以从中心节点或AMF1获取共享数据1。
AMF2向网络存储网元发送网元注册请求时,携带共享数据1的标识信息、共享数据2的标识信息、NF SET1的标识信息和共享等级,该共享等级用于指示以网元集合的粒度进行数据共享。网络存储网元判断本地是否存储有与该NF SET1的标识信息及共享数据1的标识信息对应的共享数据1。如果存储有共享数据1,则不需要再从其它网元获取共享数据1。如果没有存储共享数据1,则可以从中心节点或AMF2获取共享数据1。以及,网络存储网元判断本地是否存储有与该NF SET1的标识信息及共享数据2的标识信息对应的共享数据2。如果存储有共享数据2,则不需要再从其它网元获取共享数据2。如果没有存储共享数据2,则可以从中心节点或AMF2获取共享数据2。
AMF3向网络存储网元发送网元注册请求时,携带共享数据2的标识信息、NF SET1的标识信息和共享等级,该共享等级用于指示以网元集合的粒度进行数据共享。网络存储网元判断本地是否存储有与该NF SET1的标识信息及共享数据2的标识信息对应的共享数据2。如果存储有共享数据2,则不需要再从其它网元获取共享数据2。如果没有存储共享数据2,则可以从中心节点或AMF3获取共享数据2。
第二种方法,共享等级用于指示以网络的粒度进行数据共享
这里的网络可以用DNN进行标识,或者用网络切片标识(即S-NSSAI)进行标识,或者用数据网络和网络切片标识进行标识。
以DNN+S-NSSAI标识网络为例,假设SMF1、SMF2向网络存储网元发送网元注册请求时,均携带共享数据1的标识信息、DNN1、S-NSSAI1和共享等级,该共享等级用于指示以网络的粒度进行数据共享。网络存储网元判断本地是否存储有与共享数据1的标识信息、DNN1及S-NSSAI1对应的共享数据1。如果存储有共享数据1,则不需要再从其它网元获取共享数据1。如果没有存储共享数据1,则可以从中心节点获取共享数据1,或者从SMF1或SMF2获取共享数据1。该示例中,SMF1、SMF2是上述第一网元的具体示例。SMF1和SMF2均对应共享数据1。
假设SMF3、SMF4向网络存储网元发送网元注册请求时,均携带共享数据2的标识信息、DNN1、S-NSSAI2和共享等级,该共享等级用于指示以网络的粒度进行数据共享。网络存储网元判断本地是否存储有与共享数据2的标识信息、DNN1及S-NSSAI2对应的共享数据2。如果存储有共享数据2,则不需要再从其它网元获取共享数据2。如果没有存储共享数据2,则可以从中心节点获取共享数据2,或者从SMF3或SMF4获取共享数据2。该示例中,SMF3、SMF4是上述第一网元的具体示例。SMF3和SMF4均对应共享数据2。
第三种方法,共享等级用于指示以中心节点的粒度进行数据共享
假设SMF1和SMF2向网络存储网元发送网元注册请求时,均携带共享数据1的标识信息、中心节 点1的标识信息和共享等级,该共享等级用于指示以中心节点的粒度进行数据共享。网络存储网元判断本地是否存储有与共享数据1的标识信息及中心节点1的标识信息对应的共享数据1。如果存储有共享数据1,则不需要再从其它网元获取共享数据1。如果没有存储共享数据1,则可以从中心节点1获取共享数据1。这里的SMF1、SMF2是上述第一网元的具体示例。SMF1和SMF2均对应共享数据1。
假设SMF3和SMF4向网络存储网元发送网元注册请求时,均携带共享数据2的标识信息、中心节点2的标识信息和共享等级,该共享等级用于指示以中心节点的粒度进行数据共享。网络存储网元判断本地是否存储有与共享数据2的标识信息及中心节点2的标识信息对应的共享数据2。如果存储有共享数据2,则不需要再从其它网元获取共享数据2。如果没有存储共享数据2,则可以从中心节点2获取共享数据2。这里的SMF3、SMF4是上述第一网元的具体示例。SMF3和SMF4均对应共享数据2。
需要说明的是,上述方法1、方法2和方法3中的任意两个或三个方法之间可以结合实施,本申请对此不做限定。比如某个NF网元需要注册的信息包括信息1、信息2和信息3,该信息1与其它NF网元之间按照网元集合的粒度进行共享,该信息2与其它NF网元之间按照网络的粒度进行共享,该信息3与其它NF网元之间按照中心节点的粒度进行共享。
图5为本申请实施例提供的一种通信方法的流程示意图。该流程也称为网元发现流程。该方法可以结合上述图4的实施例进行实施,也可以单独实施,本申请不做限定。
该方法包括以下步骤:
步骤501,第二网元向网络存储网元发送网元发现请求。相应地,网络存储网元接收该网元发现请求。
该网元发现请求中包括网元类型(NF type)和查询条件。该查询条件比如包括特定终端设备的用户永久标识(subscription permanent identifier,SUPI)或能力信息,表示向网络存储网元请求查询为特定终端设备提供服务的NF网元,或者查询满足指定的能力信息的NF网元。
步骤502,网络存储网元向第二网元发送网元发现响应。相应地,第二网元接收该网元发现响应。
比如,当网络存储网元根据网元发现请求中的网元类型和查询条件,选择第一网元,则在网元发现响应包括第一网元的标识信息和共享数据的标识信息,该共享数据的标识信息用于第二网元获取共享数据。该第一网元可以是上述图4的实施例中所述的第一网元。
其中,该第一网元的类型与网元发现请求中的网元类型相同,且该第一网元满足元发现请求中的查询条件。
上述方案,网络存储网元向第二网元返回查询到的第一网元的信息时,不需要将第一网元对应的共享数据发送给第二网元,而是将第一网元对应的共享数据的标识信息发送给第二网元,从而可以减少带宽资源开销和信令开销。
在上述步骤502之后,第二网元判断本地是否已经存储有共享数据的标识信息对应的共享数据。如果已经存储共享数据的标识信息对应的共享数据,则第二网元不需要再从其它网元获取该共享数据,后续需要使用该共享数据时,从本地获取即可。如果未存储共享数据的标识信息对应的共享数据,则可以从其它网元获取该共享数据并存储该共享数据。比如可以通过以下步骤503a或步骤503b获取共享数据。
步骤503a,第二网元从网络存储网元获取共享数据。
一种实现方法中,如果第二网元之前没有订阅过该共享数据的标识信息对应的更新的共享数据,则在步骤503a之后,第二网元可以向网络存储网元发送订阅请求,该订阅请求中包括该共享数据的标识信息,订阅请求用于订阅共享数据的标识信息对应的更新的共享数据。
步骤503b,第二网元从中心节点获取共享数据。
比如,在上述步骤502的网元发现响应中还包括中心节点的信息,则第二网元根据该中心节点的信息,从中心节点获取共享数据。针对该实现方法,网络存储网元中可以不需要存储该共享数据,由中心节点存储共享数据即可。
一种实现方法中,如果第二网元之前没有订阅过该共享数据的标识信息对应的更新的共享数据,则在步骤503b之后,第二网元可以向中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,订阅请求用于订阅共享数据的标识信息对应的更新的共享数据。
上述方案,在第二网元中没有存储共享数据的标识信息对应的共享数据的情况下,第二网元从中心节点或网络存储网元获取共享数据并存储该共享数据。并且第二网元只需要存储一份该共享数据,可以减少对第二网元的存储资源的占用,提高了资源利用效率。
可以理解的是,为了实现上述实施例中功能,网络存储网元包括了执行各个功能相应的硬件结构和/或软件模块。本领域技术人员应该很容易意识到,结合本申请中所公开的实施例描述的各示例的单元及方法步骤,本申请能够以硬件或硬件和计算机软件相结合的形式来实现。某个功能究竟以硬件还是计算机软件驱动硬件的方式来执行,取决于技术方案的特定应用场景和设计约束条件。
图6和图7为本申请的实施例提供的可能的通信装置的结构示意图。这些通信装置可以用于实现上述方法实施例中网络存储网元的功能,因此也能实现上述方法实施例所具备的有益效果。在本申请的实施例中,该通信装置可以是网络存储网元,也可以是应用于网络存储网元的模块(如芯片)。
图6所示的通信装置600包括处理单元610和收发单元620。通信装置600用于实现上述图4或图5所示的方法实施例中网络存储网元的功能。
当通信装置600用于实现图4或图5所示的方法实施例中网络存储网元的功能,收发单元620,用于接收来自第一网元的网元注册请求,该网元注册请求中包括该第一网元的网元参数信息,该网元参数信息包括共享数据的标识信息和该第一网元的标识信息,该网元参数信息中不包括该共享数据的标识信息对应的该共享数据;处理单元610,用于存储该网元参数信息。
一种可能的实现方法中,该通信装置600已存储有该共享数据。
一种可能的实现方法中,收发单元620,还用于向中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
一种可能的实现方法中,处理单元610,还用于获取该共享数据,并存储该共享数据。
一种可能的实现方法中,处理单元610,具体用于从该第一网元获取该共享数据。
一种可能的实现方法中,收发单元620,还用于向该第一网元发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
一种可能的实现方法中,该注册请求还包括中心节点的信息;处理单元610,具体用于从该中心节点获取该共享数据。
一种可能的实现方法中,收发单元620,还用于向该中心节点发送订阅请求,该订阅请求中包括该共享数据的标识信息,该订阅请求用于订阅该共享数据的标识信息对应的更新的共享数据。
一种可能的实现方法中,该注册请求还包括共享等级,该共享等级用于指示进行数据共享的粒度。
一种可能的实现方法中,该注册请求还包括该第一网元归属的第一网元集合的标识信息,该共享等级具体用于指示以网元集合的粒度进行数据共享;通信装置600存储的该共享数据对应该第一网元集合的标识信息和该共享数据的标识信息。
一种可能的实现方法中,该注册请求还包括该第一网元对应的网络的标识信息,该共享等级具体用于指示以网络的粒度进行数据共享,该网络的标识信息包括数据网络名称和/或网络切片标识;该通信装置600存储的该共享数据对应该网络的标识信息和该共享数据的标识信息。
一种可能的实现方法中,该注册请求还包括中心节点的信息,该共享等级具体用于指示以中心节点的粒度进行数据共享;该通信装置600存储的该共享数据对应该中心节点的信息和该共享数据的标识信息。
一种可能的实现方法中收发单元620,还用于接收来自第二网元的网元发现请求,该网元发现请求中包括网元类型和查询条件;向该第二网元发送网元发现响应,该网元发现响应包括该第一网元的标识信息和该共享数据的标识信息,该共享数据的标识信息用于该第二网元获取该共享数据;其中,该第一网元的类型与该网元类型相同,该第一网元满足该查询条件。
一种可能的实现方法中,该网元发现响应还包括中心节点的信息,该中心节点的信息用于该第二网元向该中心节点获取该共享数据。
有关上述处理单元610和收发单元620更详细的描述可以直接参考图4或图5所示的方法实施例中相关描述直接得到,这里不加赘述。
图7所示的通信装置700包括处理器710和接口电路720。处理器710和接口电路720之间相互耦合。可以理解的是,接口电路720可以为收发器或输入输出接口。可选的,通信装置700还可以包括存储器730,用于存储处理器710执行的指令或存储处理器710运行指令所需要的输入数据或存储处理器710运行指令后产生的数据。
当通信装置700用于实现图4或图5所示的方法时,处理器710用于实现上述处理单元610的功能,接口电路720用于实现上述收发单元620的功能。
可以理解的是,本申请的实施例中的处理器可以是中央处理单元(Central Processing Unit,CPU),还可以是其它通用处理器、数字信号处理器(Digital Signal Processor,DSP)、专用集成电路(Application Specific Integrated Circuit,ASIC)、现场可编程门阵列(Field Programmable Gate Array,FPGA)或者其它可编程逻辑器件、晶体管逻辑器件,硬件部件或者其任意组合。通用处理器可以是微处理器,也可以是任何常规的处理器。
本申请的实施例中的方法步骤可以通过硬件的方式来实现,也可以由处理器执行软件指令的方式来实现。软件指令可以由相应的软件模块组成,软件模块可以被存放于随机存取存储器、闪存、只读存储器、可编程只读存储器、可擦除可编程只读存储器、电可擦除可编程只读存储器、寄存器、硬盘、移动硬盘、CD-ROM或者本领域熟知的任何其它形式的存储介质中。一种示例性的存储介质耦合至处理器,从而使处理器能够从该存储介质读取信息,且可向该存储介质写入信息。当然,存储介质也可以是处理器的组成部分。处理器和存储介质可以位于ASIC中。另外,该ASIC可以位于基站或终端设备中。当然,处理器和存储介质也可以作为分立组件存在于基站或终端设备中。
在上述实施例中,可以全部或部分地通过软件、硬件、固件或者其任意组合来实现。当使用软件实现时,可以全部或部分地以计算机程序产品的形式实现。所述计算机程序产品包括一个或多个计算机程序或指令。在计算机上加载和执行所述计算机程序或指令时,全部或部分地执行本申请实施例所述的流程或功能。所述计算机可以是通用计算机、专用计算机、计算机网络、基站、用户设备或者其它可编程装置。所述计算机程序或指令可以存储在计算机可读存储介质中,或者从一个计算机可读存储介质向另一个计算机可读存储介质传输,例如,所述计算机程序或指令可以从一个网站站点、计算机、服务器或数据中心通过有线或无线方式向另一个网站站点、计算机、服务器或数据中心进行传输。所述计算机可读存储介质可以是计算机能够存取的任何可用介质或者是集成一个或多个可用介质的服务器、数据中心等数据存储设备。所述可用介质可以是磁性介质,例如,软盘、硬盘、磁带;也可以是光介质,例如,数字视频光盘;还可以是半导体介质,例如,固态硬盘。该计算机可读存储介质可以是易失性或非易失性存储介质,或可包括易失性和非易失性两种类型的存储介质。
在本申请的各个实施例中,如果没有特殊说明以及逻辑冲突,不同的实施例之间的术语和/或描述具有一致性、且可以相互引用,不同的实施例中的技术特征根据其内在的逻辑关系可以组合形成新的实施例。
本申请中,“至少一个”是指一个或者多个,“多个”是指两个或两个以上。“和/或”,描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示:单独存在A,同时存在A和B,单独存在B的情况,其中A,B可以是单数或者复数。在本申请的文字描述中,字符“/”,一般表示前后关联对象是一种“或”的关系;在本申请的公式中,字符“/”,表示前后关联对象是一种“相除”的关系。
可以理解的是,在本申请的实施例中涉及的各种数字编号仅为描述方便进行的区分,并不用来限制本申请的实施例的范围。上述各过程的序号的大小并不意味着执行顺序的先后,各过程的执行顺序应以其功能和内在逻辑确定。

Claims (18)

  1. 一种通信方法,其特征在于,包括:
    网络存储网元接收来自第一网元的网元注册请求,所述网元注册请求中包括所述第一网元的网元参数信息,所述网元参数信息包括共享数据的标识信息和所述第一网元的标识信息,所述网元参数信息中不包括所述共享数据的标识信息对应的所述共享数据;
    所述网络存储网元存储所述网元参数信息。
  2. 如权利要求1所述的方法,其特征在于,
    所述网络存储网元已存储有所述共享数据。
  3. 如权利要求2所述的方法,其特征在于,所述方法还包括:
    所述网络存储网元向中心节点发送订阅请求,所述订阅请求中包括所述共享数据的标识信息,所述订阅请求用于订阅所述共享数据的标识信息对应的更新的共享数据。
  4. 如权利要求1所述的方法,其特征在于,所述方法还包括:
    所述网络存储网元获取所述共享数据,并存储所述共享数据。
  5. 如权利要求4所述的方法,其特征在于,所述网络存储网元获取所述共享数据,包括:
    所述网络存储网元从所述第一网元获取所述共享数据。
  6. 如权利要求5所述的方法,其特征在于,所述方法还包括:
    所述网络存储网元向所述第一网元发送订阅请求,所述订阅请求中包括所述共享数据的标识信息,所述订阅请求用于订阅所述共享数据的标识信息对应的更新的共享数据。
  7. 如权利要求4所述的方法,其特征在于,所述注册请求还包括中心节点的信息;
    所述网络存储网元获取所述共享数据,包括:
    所述网络存储网元从所述中心节点获取所述共享数据。
  8. 如权利要求7所述的方法,其特征在于,所述方法还包括:
    所述网络存储网元向所述中心节点发送订阅请求,所述订阅请求中包括所述共享数据的标识信息,所述订阅请求用于订阅所述共享数据的标识信息对应的更新的共享数据。
  9. 如权利要求2至8中任一项所述的方法,其特征在于,所述注册请求还包括共享等级,所述共享等级用于指示进行数据共享的粒度。
  10. 如权利要求9所述的方法,其特征在于,所述注册请求还包括所述第一网元归属的第一网元集合的标识信息,所述共享等级具体用于指示以网元集合的粒度进行数据共享;
    所述网络存储网元存储的所述共享数据对应所述第一网元集合的标识信息和所述共享数据的标识信息。
  11. 如权利要求9所述的方法,其特征在于,所述注册请求还包括所述第一网元对应的网络的标识信息,所述共享等级具体用于指示以网络的粒度进行数据共享,所述网络的标识信息包括数据网络名称和/或网络切片标识;
    所述网络存储网元存储的所述共享数据对应所述网络的标识信息和所述共享数据的标识信息。
  12. 如权利要求9所述的方法,其特征在于,所述注册请求还包括中心节点的信息,所述共享等级具体用于指示以中心节点的粒度进行数据共享;
    所述网络存储网元存储的所述共享数据对应所述中心节点的信息和所述共享数据的标识信息。
  13. 如权利要求1至12中任一项所述的方法,其特征在于,所述方法还包括:
    所述网络存储网元接收来自第二网元的网元发现请求,所述网元发现请求中包括网元类型和查询条件;
    所述网络存储网元向所述第二网元发送网元发现响应,所述网元发现响应包括所述第一网元的标识信息和所述共享数据的标识信息,所述共享数据的标识信息用于所述第二网元获取所述共享数据;
    其中,所述第一网元的类型与所述网元类型相同,所述第一网元满足所述查询条件。
  14. 如权利要求13所述的方法,其特征在于,所述网元发现响应还包括中心节点的信息,所述中心节点的信息用于所述第二网元向所述中心节点获取所述共享数据。
  15. 一种通信装置,其特征在于,包括用于执行如权利要求1至14中任一项所述方法的模块。
  16. 一种计算机程序产品,其特征在于,所述计算机程序产品包括计算机程序或指令,当所述计算 机程序或指令在处理器上运行时,使得处理器执行如权利要求1至14中任一项所述方法。
  17. 一种计算机可读存储介质,其特征在于,所述存储介质中存储有计算机程序或指令,当所述计算机程序或指令被通信装置执行时,实现如权利要求1至14中任一项所述方法。
  18. 一种通信系统,其特征在于,包括用于执行如权利要求1至14中任一项所述方法的网络存储网元,和用于向所述网络存储网元发送网元注册请求的第一网元。
PCT/CN2023/120862 2022-10-13 2023-09-22 通信方法、通信装置及通信系统 WO2024078305A1 (zh)

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