Patent Application
20240373401
Examples of several of the various embodiments of the present disclosure are described herein with reference to the drawings.
In the present disclosure, various embodiments are presented as examples of how the disclosed techniques may be implemented and/or how the disclosed techniques may be practiced in environments and scenarios. It will be apparent to persons skilled in the relevant art that various changes in form and detail can be made therein without departing from the scope. In fact, after reading the description, it will be apparent to one skilled in the relevant art how to implement alternative embodiments. The present embodiments should not be limited by any of the described exemplary embodiments. The embodiments of the present disclosure will be described with reference to the accompanying drawings. Limitations, features, and/or elements from the disclosed example embodiments may be combined to create further embodiments within the scope of the disclosure. Any figures which highlight the functionality and advantages, are presented for example purposes only. The disclosed architecture is sufficiently flexible and configurable, such that it may be utilized in ways other than that shown. For example, the actions listed in any flowchart may be re-ordered or only optionally used in some embodiments.
Embodiments may be configured to operate as needed. The disclosed mechanism may be performed when certain criteria are met, for example, in a wireless device, a base station, a radio environment, a network, a combination of the above, and/or the like. Example criteria may be based, at least in part, on for example, wireless device or network node configurations, traffic load, initial system set up, packet sizes, traffic characteristics, a combination of the above, and/or the like. When the one or more criteria are met, various example embodiments may be applied. Therefore, it may be possible to implement example embodiments that selectively implement disclosed protocols.
A base station may communicate with a mix of wireless devices. Wireless devices and/or base stations may support multiple technologies, and/or multiple releases of the same technology. Wireless devices may have one or more specific capabilities. When this disclosure refers to a base station communicating with a plurality of wireless devices, this disclosure may refer to a subset of the total wireless devices in a coverage area. This disclosure may refer to, for example, a plurality of wireless devices of a given LTE or 5G release with a given capability and in a given sector of the base station. The plurality of wireless devices in this disclosure may refer to a selected plurality of wireless devices, and/or a subset of total wireless devices in a coverage area which perform according to disclosed methods, and/or the like. There may be a plurality of base stations or a plurality of wireless devices in a coverage area that may not comply with the disclosed methods, for example, those wireless devices or base stations may perform based on older releases of LTE or 5G technology.
In this disclosure, “a” and “an” and similar phrases refer to a single instance of a particular element, but should not be interpreted to exclude other instances of that element. For example, a bicycle with two wheels may be described as having “a wheel”. Any term that ends with the suffix “(s)” is to be interpreted as “at least one” and/or “one or more.” In this disclosure, the term “may” is to be interpreted as “may, for example.” In other words, the term “may” is indicative that the phrase following the term “may” is an example of one of a multitude of suitable possibilities that may, or may not, be employed by one or more of the various embodiments. The terms “comprises” and “consists of”, as used herein, enumerate one or more components of the element being described. The term “comprises” is interchangeable with “includes” and does not exclude unenumerated components from being included in the element being described. By contrast, “consists of” provides a complete enumeration of the one or more components of the element being described.
The phrases “based on”, “in response to”, “depending on”, “employing”, “using”, and similar phrases indicate the presence and/or influence of a particular factor and/or condition on an event and/or action, but do not exclude unenumerated factors and/or conditions from also being present and/or influencing the event and/or action. For example, if action X is performed “based on” condition Y, this is to be interpreted as the action being performed “based at least on” condition Y. For example, if the performance of action X is performed when conditions Y and Z are both satisfied, then the performing of action X may be described as being “based on Y”.
The term “configured” may relate to the capacity of a device whether the device is in an operational or non-operational state. Configured may refer to specific settings in a device that effect the operational characteristics of the device whether the device is in an operational or non-operational state. In other words, the hardware, software, firmware, registers, memory values, and/or the like may be “configured” within a device, whether the device is in an operational or nonoperational state, to provide the device with specific characteristics. Terms such as “a control message to cause in a device” may mean that a control message has parameters that may be used to configure specific characteristics or may be used to implement certain actions in the device, whether the device is in an operational or non-operational state.
In this disclosure, a parameter may comprise one or more information objects, and an information object may comprise one or more other objects. For example, if parameter J comprises parameter K, and parameter K comprises parameter L, and parameter L comprises parameter M, then J comprises L, and J comprises M. A parameter may be referred to as a field or information element. In an example embodiment, when one or more messages comprise a plurality of parameters, it implies that a parameter in the plurality of parameters is in at least one of the one or more messages, but does not have to be in each of the one or more messages.
This disclosure may refer to possible combinations of enumerated elements. For the sake of brevity and legibility, the present disclosure does not explicitly recite each and every permutation that may be obtained by choosing from a set of optional features. The present disclosure is to be interpreted as explicitly disclosing all such permutations. For example, the seven possible combinations of enumerated elements A, B, C consist of: (1) “A”; (2) “B”; (3) “C”; (4) “A and B”; (5) “A and C”; (6) “B and C”; and (7) “A, B, and C”. For the sake of brevity and legibility, these seven possible combinations may be described using any of the following interchangeable formulations: “at least one of A, B, and C”; “at least one of A, B, or C”; “one or more of A, B, and C”; “one or more of A, B, or C”; “A, B, and/or C”. It will be understood that impossible combinations are excluded. For example, “X and/or not-X” should be interpreted as “X or not-X”. It will be further understood that these formulations may describe alternative phrasings of overlapping and/or synonymous concepts, for example, “identifier, identification, and/or ID number”.
This disclosure may refer to sets and/or subsets. As an example, set X may be a set of elements comprising one or more elements. If every element of X is also an element of Y, then X may be referred to as a subset of Y. In this disclosure, only non-empty sets and subsets are considered. For example, if Y consists of the elements Y1, Y2, and Y3, then the possible subsets of Y are {Y1, Y2, Y3}, {Y1, Y2}, {Y1, Y3}, {Y2, Y3}, {Y1}, {Y2}, and {Y3}.
The wireless device 101 may communicate with DNs 108 via AN 102 and CN 105. In the present disclosure, the term wireless device may refer to and encompass any mobile device or fixed (non-mobile) device for which wireless communication is needed or usable. For example, a wireless device may be a telephone, smart phone, tablet, computer, laptop, sensor, meter, wearable device, Internet of Things (IoT) device, vehicle road side unit (RSU), relay node, automobile, unmanned aerial vehicle, urban air mobility, and/or any combination thereof. The term wireless device encompasses other terminology, including user equipment (UE), user terminal (UT), access terminal (AT), mobile station, handset, wireless transmit and receive unit (WTRU), and/or wireless communication device.
The AN 102 may connect wireless device 101 to CN 105 in any suitable manner. The communication direction from the AN 102 to the wireless device 101 is known as the downlink and the communication direction from the wireless device 101 to AN 102 is known as the uplink. Downlink transmissions may be separated from uplink transmissions using frequency division duplexing (FDD), time-division duplexing (TDD), and/or some combination of the two duplexing techniques. The AN 102 may connect to wireless device 101 through radio communications over an air interface. An access network that at least partially operates over the air interface may be referred to as a radio access network (RAN). The CN 105 may set up one or more end-to-end connection between wireless device 101 and the one or more DNs 108. The CN 105 may authenticate wireless device 101 and provide charging functionality.
In the present disclosure, the term base station may refer to and encompass any element of AN 102 that facilitates communication between wireless device 101 and AN 102. Access networks and base stations have many different names and implementations. The base station may be a terrestrial base station fixed to the earth. The base station may be a mobile base station with a moving coverage area. The base station may be in space, for example, on board a satellite. For example, WiFi and other standards may use the term access point. As another example, the Third-Generation Partnership Project (3GPP) has produced specifications for three generations of mobile networks, each of which uses different terminology. Third Generation (3G) and/or Universal Mobile Telecommunications System (UMTS) standards may use the term Node B. 4G, Long Term Evolution (LTE), and/or Evolved Universal Terrestrial Radio Access (E-UTRA) standards may use the term Evolved Node B (cNB). 5G and/or New Radio (NR) standards may describe AN 102 as a next-generation radio access network (NG-RAN) and may refer to base stations as Next Generation eNB (ng-cNB) and/or Generation Node B (gNB). Future standards (for example, 6G, 7G, 8G) may use new terminology to refer to the elements which implement the methods described in the present disclosure (e.g., wireless devices, base stations, ANs, CNs, and/or components thereof). A base station may be implemented as a repeater or relay node used to extend the coverage area of a donor node. A repeater node may amplify and rebroadcast a radio signal received from a donor node. A relay node may perform the same/similar functions as a repeater node but may decode the radio signal received from the donor node to remove noise before amplifying and rebroadcasting the radio signal.
The AN 102 may include one or more base stations, each having one or more coverage areas. The geographical size and/or extent of a coverage area may be defined in terms of a range at which a receiver of AN 102 can successfully receive transmissions from a transmitter (e.g., wireless device 101) operating within the coverage area (and/or vice-versa). The coverage areas may be referred to as sectors or cells (although in some contexts, the term cell refers to the carrier frequency used in a particular coverage area, rather than the coverage area itself). Base stations with large coverage areas may be referred to as macrocell base stations. Other base stations cover smaller areas, for example, to provide coverage in areas with weak macrocell coverage, or to provide additional coverage in areas with high traffic (sometimes referred to as hotspots). Examples of small cell base stations include, in order of decreasing coverage area, microcell base stations, picocell base stations, and femtocell base stations or home base stations. Together, the coverage areas of the base stations may provide radio coverage to wireless device 101 over a wide geographic area to support wireless device mobility.
A base station may include one or more sets of antennas for communicating with the wireless device 101 over the air interface. Each set of antennas may be separately controlled by the base station. Each set of antennas may have a corresponding coverage area. As an example, a base station may include three sets of antennas to respectively control three coverage areas on three different sides of the base station. The entirety of the base station (and its corresponding antennas) may be deployed at a single location. Alternatively, a controller at a central location may control one or more sets of antennas at one or more distributed locations. The controller may be, for example, a baseband processing unit that is part of a centralized or cloud RAN architecture. The baseband processing unit may be either centralized in a pool of baseband processing units or virtualized. A set of antennas at a distributed location may be referred to as a remote radio head (RRH).
The base stations of the NG-RAN 152 may be connected to the UEs 151 via Uu interfaces. The base stations of the NG-RAN 152 may be connected to each other via Xn interfaces. The base stations of the NG-RAN 152 may be connected to 5G CN 155 via NG interfaces. The Uu interface may include an air interface. The NG and Xn interfaces may include an air interface, or may consist of direct physical connections and/or indirect connections over an underlying transport network (e.g., an internet protocol (IP) transport network).
Each of the Uu, Xn, and NG interfaces may be associated with a protocol stack. The protocol stacks may include a user plane (UP) and a control plane (CP). Generally, user plane data may include data pertaining to users of the UEs 151, for example, internet content downloaded via a web browser application, sensor data uploaded via a tracking application, or email data communicated to or from an email server. Control plane data, by contrast, may comprise signaling and messages that facilitate packaging and routing of user plane data so that it can be exchanged with the DN(s). The NG interface, for example, may be divided into an NG user plane interface (NG-U) and an NG control plane interface (NG-C). The NG-U interface may provide delivery of user plane data between the base stations and the one or more user plane network functions 155B. The NG-C interface may be used for control signaling between the base stations and the one or more control plane network functions 155A. The NG-C interface may provide, for example, NG interface management, UE context management, UE mobility management, transport of NAS messages, paging, PDU session management, and configuration transfer and/or warning message transmission. In some cases, the NG-C interface may support transmission of user data (for example, a small data transmission for an IoT device).
One or more of the base stations of the NG-RAN 152 may be split into a central unit (CU) and one or more distributed units (DUs). A CU may be coupled to one or more DUs via an F1 interface. The CU may handle one or more upper layers in the protocol stack and the DU may handle one or more lower layers in the protocol stack. For example, the CU may handle RRC, PDCP, and SDAP, and the DU may handle RLC, MAC, and PHY. The one or more DUs may be in geographically diverse locations relative to the CU and/or each other. Accordingly, the CU/DU split architecture may permit increased coverage and/or better coordination.
The gNBs 152A and ng-eNBs 152B may provide different user plane and control plane protocol termination towards the UEs 151. For example, the gNB 154A may provide new radio (NR) protocol terminations over a Uu interface associated with a first protocol stack. The ng-eNBs 152B may provide Evolved UMTS Terrestrial Radio Access (E-UTRA) protocol terminations over a Uu interface associated with a second protocol stack.
The 5G-CN 155 may authenticate UEs 151, set up end-to-end connections between UEs 151 and the one or more DNs 158, and provide charging functionality. The 5G-CN 155 may be based on a service-based architecture, in which the NFs making up the 5G-CN 155 offer services to each other and to other elements of the communication network 150 via interfaces. The 5G-CN 155 may include any number of other NFs and any number of instances of each NF.
In the example of
In the example of
As shown in the example illustration of
The NFs depicted in
Each element depicted in
The UPF 305 may serve as a gateway for user plane traffic between AN 302 and DN 308. The UE 301 may connect to UPF 305 via a Uu interface and an N3 interface (also described as NG-U interface). The UPF 305 may connect to DN 308 via an N6 interface. The UPF 305 may connect to one or more other UPFs (not shown) via an N9 interface. The UE 301 may be configured to receive services through a protocol data unit (PDU) session, which is a logical connection between UE 301 and DN 308. The UPF 305 (or a plurality of UPFs if desired) may be selected by SMF 314 to handle a particular PDU session between UE 301 and DN 308. The SMF 314 may control the functions of UPF 305 with respect to the PDU session. The SMF 314 may connect to UPF 305 via an N4 interface. The UPF 305 may handle any number of PDU sessions associated with any number of UEs (via any number of ANs). For purposes of handling the one or more PDU sessions, UPF 305 may be controlled by any number of SMFs via any number of corresponding N4 interfaces.
The AMF 312 depicted in
The AMF 312 may receive, from UE 301, non-access stratum (NAS) messages transmitted in accordance with NAS protocol. NAS messages relate to communications between UE 301 and the core network. Although NAS messages may be relayed to AMF 312 via AN 302, they may be described as communications via the N1 interface. NAS messages may facilitate UE registration and mobility management, for example, by authenticating, identifying, configuring, and/or managing a connection of UE 301. NAS messages may support session management procedures for maintaining user plane connectivity and quality of service (QOS) of a session between UE 301 and DN 309. If the NAS message involves session management, AMF 312 may send the NAS message to SMF 314. NAS messages may be used to transport messages between UE 301 and other components of the core network (e.g., core network components other than AMF 312 and SMF 314). The AMF 312 may act on a particular NAS message itself, or alternatively, forward the NAS message to an appropriate core network function (e.g., SMF 314, etc.)
The SMF 314 depicted in
The PCF 320 may provide, to other NFs, services relating to policy rules. The PCF 320 may use subscription data and information about network conditions to determine policy rules and then provide the policy rules to a particular NF which may be responsible for enforcement of those rules. Policy rules may relate to policy control for access and mobility, and may be enforced by the AMF. Policy rules may relate to session management, and may be enforced by the SMF 314. Policy rules may be, for example, network-specific, wireless device-specific, session-specific, or data flow-specific.
The NRF 330 may provide service discovery. The NRF 330 may belong to a particular PLMN. The NRF 330 may maintain NF profiles relating to other NFs in the communication network 300. The NF profile may include, for example, an address, PLMN, and/or type of the NF, a slice identifier, a list of the one or more services provided by the NF, and the authorization required to access the services.
The NEF 340 depicted in
The UDM 350 may provide data storage for other NFs. The UDM 350 may permit a consolidated view of network information that may be used to ensure that the most relevant information can be made available to different NFs from a single resource. The UDM 350 may store and/or retrieve information from a unified data repository (UDR). For example, UDM 350 may obtain user subscription data relating to UE 301 from the UDR.
The AUSF 360 may support mutual authentication of UE 301 by the core network and authentication of the core network by UE 301. The AUSF 360 may perform key agreement procedures and provide keying material that can be used to improve security.
The NSSF 370 may select one or more network slices to be used by the UE 301. The NSSF 370 may select a slice based on slice selection information. For example, the NSSF 370 may receive Single Network Slice Selection Assistance Information (S-NSSAI) and map the S-NSSAI to a network slice instance identifier (NSI).
The CHF 380 may control billing-related tasks associated with UE 301. For example, UPF 305 may report traffic usage associated with UE 301 to SMF 314. The SMF 314 may collect usage data from UPF 305 and one or more other UPFs. The usage data may indicate how much data is exchanged, what DN the data is exchanged with, a network slice associated with the data, or any other information that may influence billing. The SMF 314 may share the collected usage data with the CHF. The CHF may use the collected usage data to perform billing-related tasks associated with UE 301. The CHF may, depending on the billing status of UE 301, instruct SMF 314 to limit or influence access of UE 301 and/or to provide billing-related notifications to UE 301.
The NWDAF 390 may collect and analyze data from other network functions and offer data analysis services to other network functions. As an example, NWDAF 390 may collect data relating to a load level for a particular network slice instance from UPF 305, AMF 312, and/or SMF 314. Based on the collected data, NWDAF 390 may provide load level data to the PCF 320 and/or NSSF 370, and/or notify the PC220 and/or NSSF 370 if load level for a slice reaches and/or exceeds a load level threshold.
The AF 399 may be outside the core network, but may interact with the core network to provide information relating to the QoS requirements or traffic routing preferences associated with a particular application. The AF 399 may access the core network based on the exposure constraints imposed by the NEF 340. However, an operator of the core network may consider the AF 399 to be a trusted domain that can access the network directly.
The UPFs 405, 406, 407 may perform traffic detection, in which the UPFs identify and/or classify packets. Packet identification may be performed based on packet detection rules (PDR) provided by the SMF 414. A PDR may include packet detection information comprising one or more of: a source interface, a UE IP address, core network (CN) tunnel information (e.g., a CN address of an N3/N9 tunnel corresponding to a PDU session), a network instance identifier, a quality of service flow identifier (QFI), a filter set (for example, an IP packet filter set or an ethernet packet filter set), and/or an application identifier.
In addition to indicating how a particular packet is to be detected, a PDR may further indicate rules for handling the packet upon detection thereof. The rules may include, for example, forwarding action rules (FARs), multi-access rules (MARs), usage reporting rules (URRs), QoS enforcement rules (QERs), etc. For example, the PDR may comprise one or more FAR identifiers, MAR identifiers, URR identifiers, and/or QER identifiers. These identifiers may indicate the rules that are prescribed for the handling of a particular detected packet.
The UPF 405 may perform traffic forwarding in accordance with a FAR. For example, the FAR may indicate that a packet associated with a particular PDR is to be forwarded, duplicated, dropped, and/or buffered. The FAR may indicate a destination interface, for example, “access” for downlink or “core” for uplink. If a packet is to be buffered, the FAR may indicate a buffering action rule (BAR). As an example, UPF 405 may perform data buffering of a certain number downlink packets if a PDU session is deactivated.
The UPF 405 may perform QoS enforcement in accordance with a QER. For example, the QER may indicate a guaranteed bitrate that is authorized and/or a maximum bitrate to be enforced for a packet associated with a particular PDR. The QER may indicate that a particular guaranteed and/or maximum bitrate may be for uplink packets and/or downlink packets. The UPF 405 may mark packets belonging to a particular QoS flow with a corresponding QFI. The marking may enable a recipient of the packet to determine a QoS of the packet.
The UPF 405 may provide usage reports to the SMF 414 in accordance with a URR. The URR may indicate one or more triggering conditions for generation and reporting of the usage report, for example, immediate reporting, periodic reporting, a threshold for incoming uplink traffic, or any other suitable triggering condition. The URR may indicate a method for measuring usage of network resources, for example, data volume, duration, and/or event.
As noted above, the DNs 408, 409 may comprise public DNS (e.g., the Internet), private DNs (e.g., private, internal corporate-owned DNs), and/or intra-operator DNs. Each DN may provide an operator service and/or a third-party service. The service provided by a DN may be the Internet, an IP multimedia subsystem (IMS), an augmented or virtual reality network, an edge computing or mobile edge computing (MEC) network, etc. Each DN may be identified using a data network name (DNN). The UE 401 may be configured to establish a first logical connection with DN 408 (a first PDU session), a second logical connection with DN 409 (a second PDU session), or both simultaneously (first and second PDU sessions).
Each PDU session may be associated with at least one UPF configured to operate as a PDU session anchor (PSA, or “anchor”). The anchor may be a UPF that provides an N6 interface with a DN.
In the example of
As noted above, UPF 406 may be the anchor for the second PDU session between UE 401 and DN 409. Although the anchor for the first and second PDU sessions are associated with different UPFs in
The SMF 414 may allocate, manage, and/or assign an IP address to UE 401, for example, upon establishment of a PDU session. The SMF 414 may maintain an internal pool of IP addresses to be assigned. The SMF 414 may, if necessary, assign an IP address provided by a dynamic host configuration protocol (DHCP) server or an authentication, authorization, and accounting (AAA) server. IP address management may be performed in accordance with a session and service continuity (SSC) mode. In SSC mode 1, an IP address of UE 401 may be maintained (and the same anchor UPF may be used) as the wireless device moves within the network. In SSC mode 2, the IP address of UE 401 changes as UE 401 moves within the network (e.g., the old IP address and UPF may be abandoned and a new IP address and anchor UPF may be established). In SSC mode 3, it may be possible to maintain an old IP address (similar to SSC mode 1) temporarily while establishing a new IP address (similar to SSC mode 2), thus combining features of SSC modes 1 and 2. Applications that are sensitive to IP address changes may operate in accordance with SSC mode 1.
UPF selection may be controlled by SMF 414. For example, upon establishment and/or modification of a PDU session between UE 401 and DN 408, SMF 414 may select UPF 405 as the anchor for the PDU session and/or UPF 407 as an intermediate UPF. Criteria for UPF selection include path efficiency and/or speed between AN 402 and DN 408. The reliability, load status, location, slice support and/or other capabilities of candidate UPFs may also be considered.
The AN 403 may be, for example, a wireless land area network (WLAN) operating in accordance with the IEEE 802.11 standard. The UE 401 may connect to AN 403, via an interface Y1, in whatever manner is prescribed for AN 403. The connection to AN 403 may or may not involve authentication. The UE 401 may obtain an IP address from AN 403. The UE 401 may determine to connect to core network 400B and select untrusted access for that purpose. The AN 403 may communicate with N3IWF 404 via a Y2 interface. After selecting untrusted access, the UE 401 may provide N3IWF 404 with sufficient information to select an AMF. The selected AMF may be, for example, the same AMF that is used by UE 401 for 3GPP access (AMF 412 in the present example). The N3IWF 404 may communicate with AMF 412 via an N2 interface. The UPF 405 may be selected and N3IWF 404 may communicate with UPF 405 via an N3 interface. The UPF 405 may be a PDU session anchor (PSA) and may remain the anchor for the PDU session even as UE 401 shifts between trusted access and untrusted access.
The UE 501 may not be a subscriber of the VPLMN. The AMF 512 may authorize UE 501 to access the network based on, for example, roaming restrictions that apply to UE 501. In order to obtain network services provided by the VPLMN, it may be necessary for the core network of the VPLMN to interact with core network elements of a HPLMN of UE 501, in particular, a PCF 521, an NRF 531, an NEF 541, a UDM 551, and/or an AUSF 561. The VPLMN and HPLMN may communicate using an N32 interface connecting respective security edge protection proxies (SEPPs). In
The VSEPP 590 and the HSEPP 591 communicate via an N32 interface for defined purposes while concealing information about each PLMN from the other. The SEPPs may apply roaming policies based on communications via the N32 interface. The PCF 520 and PCF 521 may communicate via the SEPPs to exchange policy-related signaling. The NRF 530 and NRF 531 may communicate via the SEPPs to enable service discovery of NFs in the respective PLMNs. The VPLMN and HPLMN may independently maintain NEF 540 and NEF 541. The NSSF 570 and NSSF 571 may communicate via the SEPPs to coordinate slice selection for UE 501. The HPLMN may handle all authentication and subscription related signaling. For example, when the UE 501 registers or requests service via the VPLMN, the VPLMN may authenticate UE 501 and/or obtain subscription data of UE 501 by accessing, via the SEPPs, the UDM 551 and AUSF 561 of the HPLMN.
The core network architecture 500 depicted in
Network architecture 600A illustrates an un-sliced physical network corresponding to a single logical network. The network architecture 600A comprises a user plane wherein UEs 601A, 601B, 601C (collectively, UEs 601) have a physical and logical connection to a DN 608 via an AN 602 and a UPF 605. The network architecture 600A comprises a control plane wherein an AMF 612 and a SMF 614 control various aspects of the user plane.
The network architecture 600A may have a specific set of characteristics (e.g., relating to maximum bit rate, reliability, latency, bandwidth usage, power consumption, etc.). This set of characteristics may be affected by the nature of the network elements themselves (e.g., processing power, availability of free memory, proximity to other network elements, etc.) or the management thereof (e.g., optimized to maximize bit rate or reliability, reduce latency or power bandwidth usage, etc.). The characteristics of network architecture 600A may change over time, for example, by upgrading equipment or by modifying procedures to target a particular characteristic. However, at any given time, network architecture 600A will have a single set of characteristics that may or may not be optimized for a particular use case. For example, UEs 601A, 601B, 601C may have different requirements, but network architecture 600A can only be optimized for one of the three.
Network architecture 600B is an example of a sliced physical network divided into multiple logical networks. In
Each network slice may be tailored to network services having different sets of characteristics. For example, slice A may correspond to enhanced mobile broadband (cMBB) service. Mobile broadband may refer to internet access by mobile users, commonly associated with smartphones. Slice B may correspond to ultra-reliable low-latency communication (URLLC), which focuses on reliability and speed. Relative to cMBB, URLLC may improve the feasibility of use cases such as autonomous driving and telesurgery. Slice C may correspond to massive machine type communication (mMTC), which focuses on low-power services delivered to a large number of users. For example, slice C may be optimized for a dense network of battery-powered sensors that provide small amounts of data at regular intervals. Many mMTC use cases would be prohibitively expensive if they operated using an eMBB or URLLC network.
If the service requirements for one of the UEs 601 changes, then the network slice serving that UE can be updated to provide better service. Moreover, the set of network characteristics corresponding to eMBB, URLLC, and mMTC may be varied, such that differentiated species of eMBB, URLLC, and mMTC are provided. Alternatively, network operators may provide entirely new services in response to, for example, customer demand.
In
Network slice selection may be controlled by an AMF, or alternatively, by a separate network slice selection function (NSSF). For example, a network operator may define and implement distinct network slice instances (NSIs). Each NSI may be associated with single network slice selection assistance information (S-NSSAI). The S-NSSAI may include a particular slice/service type (SST) indicator (indicating eMBB, URLLC, mMTC, etc.). as an example, a particular tracking area may be associated with one or more configured S-NSSAIs. UEs may identify one or more requested and/or subscribed S-NSSAIs (e.g., during registration). The network may indicate to the UE one or more allowed and/or rejected S-NSSAIs.
The S-NSSAI may further include a slice differentiator (SD) to distinguish between different tenants of a particular slice and/or service type. For example, a tenant may be a customer (e.g., vehicle manufacture, service provider, etc.) of a network operator that obtains (for example, purchases) guaranteed network resources and/or specific policies for handling its subscribers. The network operator may configure different slices and/or slice types, and use the SD to determine which tenant is associated with a particular slice.
The layers may be associated with an open system interconnection (OSI) model of computer networking functionality. In the OSI model, layer 1 may correspond to the bottom layer, with higher layers on top of the bottom layer. Layer 1 may correspond to a physical layer, which is concerned with the physical infrastructure used for transfer of signals (for example, cables, fiber optics, and/or radio frequency transceivers). In New Radio (NR), layer 1 may comprise a physical layer (PHY). Layer 2 may correspond to a data link layer. Layer 2 may be concerned with packaging of data (into, e.g., data frames) for transfer, between nodes of the network, using the physical infrastructure of layer 1. In NR, layer 2 may comprise a media access control layer (MAC), a radio link control layer (RLC), a packet data convergence layer (PDCP), and a service data application protocol layer (SDAP).
Layer 3 may correspond to a network layer. Layer 3 may be concerned with routing of the data which has been packaged in layer 2. Layer 3 may handle prioritization of data and traffic avoidance. In NR, layer 3 may comprise a radio resource control layer (RRC) and a non-access stratum layer (NAS). Layers 4 through 7 may correspond to a transport layer, a session layer, a presentation layer, and an application layer. The application layer interacts with an end user to provide data associated with an application. In an example, an end user implementing the application may generate data associated with the application and initiate sending of that information to a targeted data network (e.g., the Internet, an application server, etc.). Starting at the application layer, each layer in the OSI model may manipulate and/or repackage the information and deliver it to a lower layer. At the lowest layer, the manipulated and/or repackaged information may be exchanged via physical infrastructure (for example, electrically, optically, and/or electromagnetically). As it approaches the targeted data network, the information will be unpackaged and provided to higher and higher layers, until it once again reaches the application layer in a form that is usable by the targeted data network (e.g., the same form in which it was provided by the end user). To respond to the end user, the data network may perform this procedure in reverse.
The NAS may be concerned with the non-access stratum, in particular, communication between the UE 701 and the core network (e.g., the AMF 712). Lower layers may be concerned with the access stratum, for example, communication between the UE 701 and the gNB 702. Messages sent between the UE 701 and the core network may be referred to as NAS messages. In an example, a NAS message may be relayed by the gNB 702, but the content of the NAS message (e.g., information elements of the NAS message) may not be visible to the gNB 702.
PDCP 761 and PDCP 762 may perform header compression and/or decompression. Header compression may reduce the amount of data transmitted over the physical layer. The PDCP 761 and PDCP 762 may perform ciphering and/or deciphering. Ciphering may reduce unauthorized decoding of data transmitted over the physical layer (e.g., intercepted on an air interface), and protect data integrity (e.g., to ensure control messages originate from intended sources). The PDCP 761 and PDCP 762 may perform retransmissions of undelivered packets, in-sequence delivery and reordering of packets, duplication of packets, and/or identification and removal of duplicate packets. In a dual connectivity scenario, PDCP 761 and PDCP 762 may perform mapping between a split radio bearer and RLC channels.
RLC 751 and RLC 752 may perform segmentation, retransmission through Automatic Repeat Request (ARQ). The RLC 751 and RLC 752 may perform removal of duplicate data units received from MAC 741 and MAC 742, respectively. The RLCs 213 and 223 may provide RLC channels as a service to PDCPs 214 and 224, respectively.
MAC 741 and MAC 742 may perform multiplexing and/or demultiplexing of logical channels. MAC 741 and MAC 742 may map logical channels to transport channels. In an example, UE 701 may, in MAC 741, multiplex data units of one or more logical channels into a transport block. The UE 701 may transmit the transport block to the gNB 702 using PHY 731. The gNB 702 may receive the transport block using PHY 732 and demultiplex data units of the transport blocks back into logical channels. MAC 741 and MAC 742 may perform error correction through Hybrid Automatic Repeat Request (HARQ), logical channel prioritization, and/or padding.
PHY 731 and PHY 732 may perform mapping of transport channels to physical channels. PHY 731 and PHY 732 may perform digital and analog signal processing functions (e.g., coding/decoding and modulation/demodulation) for sending and receiving information (e.g., transmission via an air interface). PHY 731 and PHY 732 may perform multi-antenna mapping.
In the example of
One or more applications associated with UE 801 may generate uplink packets 812A-812E associated with the PDU session 810. In order to work within the QoS model, UE 801 may apply QoS rules 814 to uplink packets 812A-812E. The QoS rules 814 may be associated with PDU session 810 and may be determined and/or provided to the UE 801 when PDU session 810 is established and/or modified. Based on QoS rules 814, UE 801 may classify uplink packets 812A-812E, map each of the uplink packets 812A-812E to a QoS flow, and/or mark uplink packets 812A-812E with a QoS flow indicator (QFI). As a packet travels through the network, and potentially mixes with other packets from other UEs having potentially different priorities, the QFI indicates how the packet should be handled in accordance with the QoS model. In the present illustration, uplink packets 812A, 812B are mapped to QoS flow 816A, uplink packet 812C is mapped to QoS flow 816B, and the remaining packets are mapped to QoS flow 816C.
The QoS flows may be the finest granularity of QOS differentiation in a PDU session. In the figure, three QoS flows 816A-816C are illustrated. However, it will be understood that there may be any number of QoS flows. Some QoS flows may be associated with a guaranteed bit rate (GBR QoS flows) and others may have bit rates that are not guaranteed (non-GBR QoS flows). QoS flows may also be subject to per-UE and per-session aggregate bit rates. One of the QoS flows may be a default QoS flow. The QoS flows may have different priorities. For example, QoS flow 816A may have a higher priority than QoS flow 816B, which may have a higher priority than QoS flow 816C. Different priorities may be reflected by different QoS flow characteristics. For example, QoS flows may be associated with flow bit rates. A particular QoS flow may be associated with a guaranteed flow bit rate (GFBR) and/or a maximum flow bit rate (MFBR). QoS flows may be associated with specific packet delay budgets (PDBs), packet error rates (PERs), and/or maximum packet loss rates. QoS flows may also be subject to per-UE and per-session aggregate bit rates.
In order to work within the QoS model, UE 801 may apply resource mapping rules 818 to the QoS flows 816A-816C. The air interface between UE 801 and AN 802 may be associated with resources 820. In the present illustration, QoS flow 816A is mapped to resource 820A, whereas QoS flows 816B, 816C are mapped to resource 820B. The resource mapping rules 818 may be provided by the AN 802. In order to meet QoS requirements, the resource mapping rules 818 may designate more resources for relatively high-priority QoS flows. With more resources, a high-priority QoS flow such as QoS flow 816A may be more likely to obtain the high flow bit rate, low packet delay budget, or other characteristic associated with QoS rules 814. The resources 820 may comprise, for example, radio bearers. The radio bearers (e.g., data radio bearers) may be established between the UE 801 and the AN 802. The radio bearers in 5G, between the UE 801 and the AN 802, may be distinct from bearers in LTE, for example, Evolved Packet System (EPS) bearers between a UE and a packet data network gateway (PGW), S1 bearers between an eNB and a serving gateway (SGW), and/or an S5/S8 bearer between an SGW and a PGW.
Once a packet associated with a particular QoS flow is received at AN 802 via resource 820A or resource 820B, AN 802 may separate packets into respective QoS flows 856A-856C based on QoS profiles 828. The QoS profiles 828 may be received from an SMF. Each QoS profile may correspond to a QFI, for example, the QFI marked on the uplink packets 812A-812E. Each QoS profile may include QoS parameters such as 5G QoS identifier (5QI) and an allocation and retention priority (ARP). The QoS profile for non-GBR QoS flows may further include additional QoS parameters such as a reflective QoS attribute (RQA). The QoS profile for GBR QoS flows may further include additional QoS parameters such as a guaranteed flow bit rate (GFBR), a maximum flow bit rate (MFBR), and/or a maximum packet loss rate. The 5QI may be a standardized 5QI which have one-to-one mapping to a standardized combination of 5G QoS characteristics per well-known services. The 5QI may be a dynamically assigned 5QI which the standardized 5QI values are not defined. The 5QI may represent 5G QoS characteristics. The 5QI may comprise a resource type, a default priority level, a packet delay budget (PDB), a packet error rate (PER), a maximum data burst volume, and/or an averaging window. The resource type may indicate a non-GBR QoS flow, a GBR QoS flow or a delay-critical GBR QoS flow. The averaging window may represent a duration over which the GFBR and/or MFBR is calculated. ARP may be a priority level comprising pre-emption capability and a pre-emption vulnerability. Based on the ARP, the AN 802 may apply admission control for the QoS flows in a case of resource limitations.
The AN 802 may select one or more N3 tunnels 850 for transmission of the QoS flows 856A-856C. After the packets are divided into QoS flows 856A-856C, the packet may be sent to UPF 805 (e.g., towards a DN) via the selected one or more N3 tunnels 850. The UPF 805 may verify that the QFIs of the uplink packets 812A-812E are aligned with the QoS rules 814 provided to the UE 801. The UPF 805 may measure and/or count packets and/or provide packet metrics to, for example, a PCF.
The figure also illustrates a process for downlink. In particular, one or more applications may generate downlink packets 852A-852E. The UPF 805 may receive downlink packets 852A-852E from one or more DNs and/or one or more other UPFs. As per the QoS model, UPF 805 may apply packet detection rules (PDRs) 854 to downlink packets 852A-852E. Based on PDRs 854, UPF 805 may map packets 852A-852E into QoS flows. In the present illustration, downlink packets 852A, 852B are mapped to QoS flow 856A, downlink packet 852C is mapped to QoS flow 856B, and the remaining packets are mapped to QoS flow 856C.
The QoS flows 856A-856C may be sent to AN 802. The AN 802 may apply resource mapping rules to the QoS flows 856A-856C. In the present illustration, QoS flow 856A is mapped to resource 820A, whereas QoS flows 856B, 856C are mapped to resource 820B. In order to meet QoS requirements, the resource mapping rules may designate more resources to high-priority QoS flows.
In RRC connected 930, it may be possible for the UE to exchange data with the network (for example, the base station). The parameters necessary for exchange of data may be established and known to both the UE and the network. The parameters may be referred to and/or included in an RRC context of the UE (sometimes referred to as a UE context). These parameters may include, for example: one or more AS contexts; one or more radio link configuration parameters; bearer configuration information (e.g., relating to a data radio bearer, signaling radio bearer, logical channel, QoS flow, and/or PDU session); security information; and/or PHY, MAC, RLC, PDCP, and/or SDAP layer configuration information. The base station with which the UE is connected may store the RRC context of the UE.
While in RRC connected 930, mobility of the UE may be managed by the access network, whereas the UE itself may manage mobility while in RRC idle 910 and/or RRC inactive 920. While in RRC connected 930, the UE may manage mobility by measuring signal levels (e.g., reference signal levels) from a serving cell and neighboring cells and reporting these measurements to the base station currently serving the UE. The network may initiate handover based on the reported measurements. The RRC state may transition from RRC connected 930 to RRC idle 910 through a connection release procedure 930 or to RRC inactive 920 through a connection inactivation procedure 932.
In RRC idle 910, an RRC context may not be established for the UE. In RRC idle 910, the UE may not have an RRC connection with a base station. While in RRC idle 910, the UE may be in a sleep state for a majority of the time (e.g., to conserve battery power). The UE may wake up periodically (e.g., once in every discontinuous reception cycle) to monitor for paging messages from the access network. Mobility of the UE may be managed by the UE through a procedure known as cell reselection. The RRC state may transition from RRC idle 910 to RRC connected 930 through a connection establishment procedure 913, which may involve a random access procedure, as discussed in greater detail below.
In RRC inactive 920, the RRC context previously established is maintained in the UE and the base station. This may allow for a fast transition to RRC connected 930 with reduced signaling overhead as compared to the transition from RRC idle 910 to RRC connected 930. The RRC state may transition to RRC connected 930 through a connection resume procedure 923. The RRC state may transition to RRC idle 910 though a connection release procedure 921 that may be the same as or similar to connection release procedure 931.
An RRC state may be associated with a mobility management mechanism. In RRC idle 910 and RRC inactive 920, mobility may be managed by the UE through cell reselection. The purpose of mobility management in RRC idle 910 and/or RRC inactive 920 is to allow the network to be able to notify the UE of an event via a paging message without having to broadcast the paging message over the entire mobile communications network. The mobility management mechanism used in RRC idle 910 and/or RRC inactive 920 may allow the network to track the UE on a cell-group level so that the paging message may be broadcast over the cells of the cell group that the UE currently resides within instead of the entire communication network. Tracking may be based on different granularities of grouping. For example, there may be three levels of cell-grouping granularity: individual cells; cells within a RAN area identified by a RAN area identifier (RAI); and cells within a group of RAN areas, referred to as a tracking area and identified by a tracking area identifier (TAI).
Tracking areas may be used to track the UE at the CN level. The CN may provide the UE with a list of TAIs associated with a UE registration area. If the UE moves, through cell reselection, to a cell associated with a TAI not included in the list of TAIs associated with the UE registration area, the UE may perform a registration update with the CN to allow the CN to update the UE's location and provide the UE with a new the UE registration area.
RAN areas may be used to track the UE at the RAN level. For a UE in RRC inactive 920 state, the UE may be assigned a RAN notification area. A RAN notification area may comprise one or more cell identities, a list of RAIs, and/or a list of TAIs. In an example, a base station may belong to one or more RAN notification areas. In an example, a cell may belong to one or more RAN notification areas. If the UE moves, through cell reselection, to a cell not included in the RAN notification area assigned to the UE, the UE may perform a notification area update with the RAN to update the UE's RAN notification area.
A base station storing an RRC context for a UE or a last serving base station of the UE may be referred to as an anchor base station. An anchor base station may maintain an RRC context for the UE at least during a period of time that the UE stays in a RAN notification area of the anchor base station and/or during a period of time that the UE stays in RRC inactive 920.
In RM deregistered 940, the UE is not registered with the network, and the UE is not reachable by the network. In order to be reachable by the network, the UE must perform an initial registration. As an example, the UE may register with an AMF of the network. If registration is rejected (registration reject 944), then the UE remains in RM deregistered 940. If registration is accepted (registration accept 945), then the UE transitions to RM registered 950. While the UE is RM registered 950, the network may store, keep, and/or maintain a UE context for the UE. The UE context may be referred to as wireless device context. The UE context corresponding to network registration (maintained by the core network) may be different from the RRC context corresponding to RRC state (maintained by an access network, e.g., a base station). The UE context may comprise a UE identifier and a record of various information relating to the UE, for example, UE capability information, policy information for access and mobility management of the UE, lists of allowed or established slices or PDU sessions, and/or a registration area of the UE (i.e., a list of tracking areas covering the geographical area where the wireless device is likely to be found).
While the UE is RM registered 950, the network may store the UE context of the UE, and if necessary use the UE context to reach the UE. Moreover, some services may not be provided by the network unless the UE is registered. The UE may update its UE context while remaining in RM registered 950 (registration update accept 955). For example, if the UE leaves one tracking area and enters another tracking area, the UE may provide a tracking area identifier to the network. The network may deregister the UE, or the UE may deregister itself (deregistration 954). For example, the network may automatically deregister the wireless device if the wireless device is inactive for a certain amount of time. Upon deregistration, the UE may transition to RM deregistered 940.
In CM idle 960, the UE does not have a non access stratum (NAS) signaling connection with the network. As a result, the UE can not communicate with core network functions. The UE may transition to CM connected 970 by establishing an AN signaling connection (AN signaling connection establishment 967). This transition may be initiated by sending an initial NAS message. The initial NAS message may be a registration request (e.g., if the UE is RM deregistered 940) or a service request (e.g., if the UE is RM registered 950). If the UE is RM registered 950, then the UE may initiate the AN signaling connection establishment by sending a service request, or the network may send a page, thereby triggering the UE to send the service request.
In CM connected 970, the UE can communicate with core network functions using NAS signaling. As an example, the UE may exchange NAS signaling with an AMF for registration management purposes, service request procedures, and/or authentication procedures. As another example, the UE may exchange NAS signaling, with an SMF, to establish and/or modify a PDU session. The network may disconnect the UE, or the UE may disconnect itself (AN signaling connection release 976). For example, if the UE transitions to RM deregistered 940, then the UE may also transition to CM idle 960. When the UE transitions to CM idle 960, the network may deactivate a user plane connection of a PDU session of the UE.
Registration may be initiated by a UE for the purposes of obtaining authorization to receive services, enabling mobility tracking, enabling reachability, or other purposes. The UE may perform an initial registration as a first step toward connection to the network (for example, if the UE is powered on, airplane mode is turned off, etc.). Registration may also be performed periodically to keep the network informed of the UE's presence (for example, while in CM-IDLE state), or in response to a change in UE capability or registration area. Deregistration (not shown in
At 1010, the UE transmits a registration request to an AN. As an example, the UE may have moved from a coverage area of a previous AMF (illustrated as AMF #1) into a coverage area of a new AMF (illustrated as AMF #2). The registration request may be a NAS message. The registration request may include a UE identifier. The AN may select an AMF for registration of the UE. For example, the AN may select a default AMF. For example, the AN may select an AMF that is already mapped to the UE (e.g., a previous AMF). The NAS registration request may include a network slice identifier and the AN may select an AMF based on the requested slice. After the AMF is selected, the AN may send the registration request to the selected AMF.
At 1020, the AMF that receives the registration request (AMF #2) performs a context transfer. The context may be a UE context, for example, an RRC context for the UE. As an example, AMF #2 may send AMF #1 a message requesting a context of the UE. The message may include the UE identifier. The message may be a Namf_Communication_UEContextTransfer message. AMF #1 may send to AMF #2 a message that includes the requested UE context. This message may be a Namf_Communication_UEContextTransfer message. After the UE context is received, the AMF #2 may coordinate authentication of the UE. After authentication is complete, AMF #2 may send to AMF #1 a message indicating that the UE context transfer is complete. This message may be a Namf_Communication_UEContextTransfer Response message.
Authentication may require participation of the UE, an AUSF, a UDM and/or a UDR (not shown). For example, the AMF may request that the AUSF authenticate the UE. For example, the AUSF may execute authentication of the UE. For example, the AUSF may get authentication data from UDM. For example, the AUSF may send a subscription permanent identifier (SUPI) to the AMF based on the authentication being successful. For example, the AUSF may provide an intermediate key to the AMF. The intermediate key may be used to derive an access-specific security key for the UE, enabling the AMF to perform security context management (SCM). The AUSF may obtain subscription data from the UDM. The subscription data may be based on information obtained from the UDM (and/or the UDR). The subscription data may include subscription identifiers, security credentials, access and mobility related subscription data and/or session related data.
At 1030, the new AMF, AMF #2, registers and/or subscribes with the UDM. AMF #2 may perform registration using a UE context management service of the UDM (Nudm UECM). AMF #2 may obtain subscription information of the UE using a subscriber data management service of the UDM (Nudm_SDM). AMF #2 may further request that the UDM notify AMF #2 if the subscription information of the UE changes. As the new AMF registers and subscribes, the old AMF, AMF #1, may deregister and unsubscribe. After deregistration, AMF #1 is free of responsibility for mobility management of the UE.
At 1040, AMF #2 retrieves access and mobility (AM) policies from the PCF. As an example, the AMF #2 may provide subscription data of the UE to the PCF. The PCF may determine access and mobility policies for the UE based on the subscription data, network operator data, current network conditions, and/or other suitable information. For example, the owner of a first UE may purchase a higher level of service than the owner of a second UE. The PCF may provide the rules associated with the different levels of service. Based on the subscription data of the respective UEs, the network may apply different policies which facilitate different levels of service.
For example, access and mobility policies may relate to service area restrictions, RAT/frequency selection priority (RFSP, where RAT stands for radio access technology), authorization and prioritization of access type (e.g., LTE versus NR), and/or selection of non-3GPP access (e.g., Access Network Discovery and Selection Policy (ANDSP)). The service area restrictions may comprise a list of tracking areas where the UE is allowed to be served (or forbidden from being served). The access and mobility policies may include a UE route selection policy (URSP)) that influences routing to an established PDU session or a new PDU session. As noted above, different policies may be obtained and/or enforced based on subscription data of the UE, location of the UE (i.e., location of the AN and/or AMF), or other suitable factors.
At 1050, AMF #2 may update a context of a PDU session. For example, if the UE has an existing PDU session, the AMF #2 may coordinate with an SMF to activate a user plane connection associated with the existing PDU session. The SMF may update and/or release a session management context of the PDU session (Nsmf_PDUSession_UpdateSMContext, Nsmf_PDUSession_ReleaseSMContext).
At 1060, AMF #2 sends a registration accept message to the AN, which forwards the registration accept message to the UE. The registration accept message may include a new UE identifier and/or a new configured slice identifier. The UE may transmit a registration complete message to the AN, which forwards the registration complete message to the AMF #2. The registration complete message may acknowledge receipt of the new UE identifier and/or new configured slice identifier.
At 1070, AMF #2 may obtain UE policy control information from the PCF. The PCF may provide an access network discovery and selection policy (ANDSP) to facilitate non-3GPP access. The PCF may provide a UE route selection policy (URSP) to facilitate mapping of particular data traffic to particular PDU session connectivity parameters. As an example, the URSP may indicate that data traffic associated with a particular application should be mapped to a particular SSC mode, network slice, PDU session type, or preferred access type (3GPP or non-3GPP).
At 1110, a UPF receives data. The data may be downlink data for transmission to a UE. The data may be associated with an existing PDU session between the UE and a DN. The data may be received, for example, from a DN and/or another UPF. The UPF may buffer the received data. In response to the receiving of the data, the UPF may notify an SMF of the received data. The identity of the SMF to be notified may be determined based on the received data. The notification may be, for example, an N4 session report. The notification may indicate that the UPF has received data associated with the UE and/or a particular PDU session associated with the UE. In response to receiving the notification, the SMF may send PDU session information to an AMF. The PDU session information may be sent in an N1N2 message transfer for forwarding to an AN. The PDU session information may include, for example, UPF tunnel endpoint information and/or QoS information.
At 1120, the AMF determines that the UE is in a CM-IDLE state. The determining at 1120 may be in response to the receiving of the PDU session information. Based on the determination that the UE is CM-IDLE, the service request procedure may proceed to 1130 and 1140, as depicted in
At 1130, the AMF pages the UE. The paging at 1130 may be performed based on the UE being CM-IDLE. To perform the paging, the AMF may send a page to the AN. The page may be referred to as a paging or a paging message. The page may be an N2 request message. The AN may be one of a plurality of ANs in a RAN notification area of the UE. The AN may send a page to the UE. The UE may be in a coverage area of the AN and may receive the page.
At 1140, the UE may request service. The UE may transmit a service request to the AMF via the AN. As depicted in
At 1150, the network may authenticate the UE. Authentication may require participation of the UE, an AUSF, and/or a UDM, for example, similar to authentication described elsewhere in the present disclosure. In some cases (for example, if the UE has recently been authenticated), the authentication at 1150 may be skipped.
At 1160, the AMF and SMF may perform a PDU session update. As part of the PDU session update, the SMF may provide the AMF with one or more UPF tunnel endpoint identifiers. In some cases (not shown in
At 1170, the AMF may send PDU session information to the AN. The PDU session information may be included in an N2 request message. Based on the PDU session information, the AN may configure a user plane resource for the UE. To configure the user plane resource, the AN may, for example, perform an RRC reconfiguration of the UE. The AN may acknowledge to the AMF that the PDU session information has been received. The AN may notify the AMF that the user plane resource has been configured, and/or provide information relating to the user plane resource configuration.
In the case of a UE-triggered service request procedure, the UE may receive, at 1170, a NAS service accept message from the AMF via the AN. After the user plane resource is configured, the UE may transmit uplink data (for example, the uplink data that caused the UE to trigger the service request procedure).
At 1180, the AMF may update a session management (SM) context of the PDU session. For example, the AMF may notify the SMF (and/or one or more other associated SMFs) that the user plane resource has been configured, and/or provide information relating to the user plane resource configuration. The AMF may provide the SMF (and/or one or more other associated SMFs) with one or more AN tunnel endpoint identifiers of the AN. After the SM context update is complete, the SMF may send an update SM context response message to the AMF.
Based on the update of the session management context, the SMF may update a PCF for purposes of policy control. For example, if a location of the UE has changed, the SMF may notify the PCF of the UE's a new location.
Based on the update of the session management context, the SMF and UPF may perform a session modification. The session modification may be performed using N4 session modification messages. After the session modification is complete, the UPF may transmit downlink data (for example, the downlink data that caused the UPF to trigger the network-triggered service request procedure) to the UE. The transmitting of the downlink data may be based on the one or more AN tunnel endpoint identifiers of the AN.
At 1210, the UE initiates PDU session establishment. The UE may transmit a PDU session establishment request to an AMF via an AN. The PDU session establishment request may be a NAS message. The PDU session establishment request may indicate: a PDU session ID; a requested PDU session type (new or existing); a requested DN (DNN); a requested network slice (S-NSSAI); a requested SSC mode; and/or any other suitable information. The PDU session ID may be generated by the UE. The PDU session type may be, for example, an Internet Protocol (IP)-based type (e.g., IPv4, IPv6, or dual stack IPv4/IPv6), an Ethernet type, or an unstructured type.
The AMF may select an SMF based on the PDU session establishment request. In some scenarios, the requested PDU session may already be associated with a particular SMF. For example, the AMF may store a UE context of the UE, and the UE context may indicate that the PDU session ID of the requested PDU session is already associated with the particular SMF. In some scenarios, the AMF may select the SMF based on a determination that the SMF is prepared to handle the requested PDU session. For example, the requested PDU session may be associated with a particular DNN and/or S-NSSAI, and the SMF may be selected based on a determination that the SMF can manage a PDU session associated with the particular DNN and/or S-NSSAI.
At 1220, the network manages a context of the PDU session. After selecting the SMF at 1210, the AMF sends a PDU session context request to the SMF. The PDU session context request may include the PDU session establishment request received from the UE at 1210. The PDU session context request may be a Nsmf_PDUSession_CreateSMContext Request and/or a Nsmf_PDUSession_UpdateSMContext Request. The PDU session context request may indicate identifiers of the UE; the requested DN; and/or the requested network slice. Based on the PDU session context request, the SMF may retrieve subscription data from a UDM. The subscription data may be session management subscription data of the UE. The SMF may subscribe for updates to the subscription data, so that the PCF will send new information if the subscription data of the UE changes. After the subscription data of the UE is obtained, the SMF may transmit a PDU session context response to the AMG. The PDU session context response may be a Nsmf_PDUSession_CreateSMContext Response and/or a Nsmf_PDUSession_UpdateSMContext Response. The PDU session context response may include a session management context ID.
At 1230, secondary authorization/authentication may be performed, if necessary. The secondary authorization/authentication may involve the UE, the AMF, the SMF, and the DN. The SMF may access the DN via a Data Network Authentication, Authorization and Accounting (DN AAA) server.
At 1240, the network sets up a data path for uplink data associated with the PDU session. The SMF may select a PCF and establish a session management policy association. Based on the association, the PCF may provide an initial set of policy control and charging rules (PCC rules) for the PDU session. When targeting a particular PDU session, the PCF may indicate, to the SMF, a method for allocating an IP address to the PDU Session, a default charging method for the PDU session, an address of the corresponding charging entity, triggers for requesting new policies, etc. The PCF may also target a service data flow (SDF) comprising one or more PDU sessions. When targeting an SDF, the PCF may indicate, to the SMF, policies for applying QoS requirements, monitoring traffic (e.g., for charging purposes), and/or steering traffic (e.g., by using one or more particular N6 interfaces).
The SMF may determine and/or allocate an IP address for the PDU session. The SMF may select one or more UPFs (a single UPF in the example of
The SMF may send PDU session management information to the AMF. The PDU session management information may be a Namf_Communication_N1N2MessageTransfer message. The PDU session management information may include the PDU session ID. The PDU session management information may be a NAS message. The PDU session management information may include N1 session management information and/or N2 session management information. The N1 session management information may include a PDU Session Establishment accept message. The PDU Session Establishment accept message may include tunneling endpoint information of the UPF and quality of service (QoS) information associated with the PDU session.
The AMF may send an N2 request to the AN. The N2 request may include the PDU Session Establishment accept message. Based on the N2 request, the AN may determine AN resources for the UE. The AN resources may be used by the UE to establish the PDU session, via the AN, with the DN. The AN may determine resources to be used for the PDU session and indicate the determined resources to the UE. The AN may send the PDU Session Establishment accept message to the UE. For example, the AN may perform an RRC reconfiguration of the UE. After the AN resources are set up, the AN may send an N2 request acknowledge to the AMF. The N2 request acknowledge may include N2 session management information, for example, the PDU session ID and tunneling endpoint information of the AN.
After the data path for uplink data is set up at 1240, the UE may optionally send uplink data associated with the PDU session. As shown in
At 1250, the network may update the PDU session context. The AMF may transmit a PDU session context update request to the SMF. The PDU session context update request may be a Nsmf_PDUSession_UpdateSMContext Request. The PDU session context update request may include the N2 session management information received from the AN. The SMF may acknowledge the PDU session context update. The acknowledgement may be a Nsmf_PDUSession_UpdateSMContext Response. The acknowledgement may include a subscription requesting that the SMF be notified of any UE mobility event. Based on the PDU session context update request, the SMF may send an N4 session message to the UPF. The N4 session message may be an N4 Session Modification Request. The N4 session message may include tunneling endpoint information of the AN. The N4 session message may include forwarding rules associated with the PDU session. In response, the UPF may acknowledge by sending an N4 session modification response.
After the UPF receives the tunneling endpoint information of the AN, the UPF may relay downlink data associated with the PDU session. As shown in
The wireless device 1310 may communicate with base station 1320 over an air interface 1370. The communication direction from wireless device 1310 to base station 1320 over air interface 1370 is known as uplink, and the communication direction from base station 1320 to wireless device 1310 over air interface 1370 is known as downlink. Downlink transmissions may be separated from uplink transmissions using FDD, TDD, and/or some combination of duplexing techniques.
The wireless device 1310 may comprise a processing system 1311 and a memory 1312. The memory 1312 may comprise one or more computer-readable media, for example, one or more non-transitory computer readable media. The memory 1312 may include instructions 1313. The processing system 1311 may process and/or execute instructions 1313. Processing and/or execution of instructions 1313 may cause wireless device 1310 and/or processing system 1311 to perform one or more functions or activities. The memory 1312 may include data (not shown). One of the functions or activities performed by processing system 1311 may be to store data in memory 1312 and/or retrieve previously-stored data from memory 1312. In an example, downlink data received from base station 1320 may be stored in memory 1312, and uplink data for transmission to base station 1320 may be retrieved from memory 1312. As illustrated in
The wireless device 1310 may comprise one or more other elements 1319. The one or more other elements 1319 may comprise software and/or hardware that provide features and/or functionalities, for example, a speaker, a microphone, a keypad, a display, a touchpad, a satellite transceiver, a universal serial bus (USB) port, a hands-free headset, a frequency modulated (FM) radio unit, a media player, an Internet browser, an electronic control unit (e.g., for a motor vehicle), and/or one or more sensors (e.g., an accelerometer, a gyroscope, a temperature sensor, a radar sensor, a lidar sensor, an ultrasonic sensor, a light sensor, a camera, a global positioning sensor (GPS) and/or the like). The wireless device 1310 may receive user input data from and/or provide user output data to the one or more one or more other elements 1319. The one or more other elements 1319 may comprise a power source. The wireless device 1310 may receive power from the power source and may be configured to distribute the power to the other components in wireless device 1310. The power source may comprise one or more sources of power, for example, a battery, a solar cell, a fuel cell, or any combination thereof.
The wireless device 1310 may transmit uplink data to and/or receive downlink data from base station 1320 via air interface 1370. To perform the transmission and/or reception, one or more of the processing system 1311, transmission processing system 1314, and/or reception system 1315 may implement open systems interconnection (OSI) functionality. As an example, transmission processing system 1314 and/or reception system 1315 may perform layer 1 OSI functionality, and processing system 1311 may perform higher layer functionality. The wireless device 1310 may transmit and/or receive data over air interface 1370 using one or more antennas 1316. For scenarios where the one or more antennas 1316 include multiple antennas, the multiple antennas may be used to perform one or more multi-antenna techniques, such as spatial multiplexing (e.g., single-user multiple-input multiple output (MIMO) or multi-user MIMO), transmit/receive diversity, and/or beamforming.
The base station 1320 may comprise a processing system 1321 and a memory 1322. The memory 1322 may comprise one or more computer-readable media, for example, one or more non-transitory computer readable media. The memory 1322 may include instructions 1323. The processing system 1321 may process and/or execute instructions 1323. Processing and/or execution of instructions 1323 may cause base station 1320 and/or processing system 1321 to perform one or more functions or activities. The memory 1322 may include data (not shown). One of the functions or activities performed by processing system 1321 may be to store data in memory 1322 and/or retrieve previously-stored data from memory 1322. The base station 1320 may communicate with wireless device 1310 using a transmission processing system 1324 and a reception processing system 1325. Although not shown in
The base station 1320 may transmit downlink data to and/or receive uplink data from wireless device 1310 via air interface 1370. To perform the transmission and/or reception, one or more of the processing system 1321, transmission processing system 1324, and/or reception system 1325 may implement OSI functionality. As an example, transmission processing system 1324 and/or reception system 1325 may perform layer 1 OSI functionality, and processing system 1321 may perform higher layer functionality. The base station 1320 may transmit and/or receive data over air interface 1370 using one or more antennas 1326. For scenarios where the one or more antennas 1326 include multiple antennas, the multiple antennas may be used to perform one or more multi-antenna techniques, such as spatial multiplexing (e.g., single-user multiple-input multiple output (MIMO) or multi-user MIMO), transmit/receive diversity, and/or beamforming.
The base station 1320 may comprise an interface system 1327. The interface system 1327 may communicate with one or more base stations and/or one or more elements of the core network via an interface 1380. The interface 1380 may be wired and/or wireless and interface system 1327 may include one or more components suitable for communicating via interface 1380. In
The deployment 1330 may comprise any number of portions of any number of instances of one or more network functions (NFs). The deployment 1330 may comprise a processing system 1331 and a memory 1332. The memory 1332 may comprise one or more computer-readable media, for example, one or more non-transitory computer readable media. The memory 1332 may include instructions 1333. The processing system 1331 may process and/or execute instructions 1333. Processing and/or execution of instructions 1333 may cause the deployment 1330 and/or processing system 1331 to perform one or more functions or activities. The memory 1332 may include data (not shown). One of the functions or activities performed by processing system 1331 may be to store data in memory 1332 and/or retrieve previously-stored data from memory 1332. The deployment 1330 may access the interface 1380 using an interface system 1337. The deployment 1330 may comprise one or more other elements 1339 analogous to one or more of the one or more other elements 1319.
One or more of the systems 1311, 1314, 1315, 1321, 1324, 1325, and/or 1331 may comprise one or more controllers and/or one or more processors. The one or more controllers and/or one or more processors may comprise, for example, a general-purpose processor, a digital signal processor (DSP), a microcontroller, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) and/or other programmable logic device, discrete gate and/or transistor logic, discrete hardware components, an on-board unit, or any combination thereof. One or more of the systems 1311, 1314, 1315, 1321, 1324, 1325, and/or 1331 may perform signal coding/processing, data processing, power control, input/output processing, and/or any other functionality that may enable wireless device 1310, base station 1320, and/or deployment 1330 to operate in a mobile communications system.
Many of the elements described in the disclosed embodiments may be implemented as modules. A module is defined here as an element that performs a defined function and has a defined interface to other elements. The modules described in this disclosure may be implemented in hardware, software in combination with hardware, firmware, wetware (e.g. hardware with a biological element) or a combination thereof, which may be behaviorally equivalent. For example, modules may be implemented as a software routine written in a computer language configured to be executed by a hardware machine (such as C, C++, Fortran, Java, Basic, Matlab or the like) or a modeling/simulation program such as Simulink, Stateflow, GNU Octave, or LabVIEWMathScript. It may be possible to implement modules using physical hardware that incorporates discrete or programmable analog, digital and/or quantum hardware. Examples of programmable hardware comprise computers, microcontrollers, microprocessors, DSPs, ASICs, FPGAs, and complex programmable logic devices (CPLDs). Computers, microcontrollers and microprocessors may be programmed using languages such as assembly, C, C++ or the like. FPGAs, ASICs and CPLDs are often programmed using hardware description languages (HDL) such as VHSIC hardware description language (VHDL) or Verilog that configure connections between internal hardware modules with lesser functionality on a programmable device. The mentioned technologies are often used in combination to achieve the result of a functional module.
The wireless device 1310, base station 1320, and/or deployment 1330 may implement timers and/or counters. A timer/counter may start at an initial value. As used herein, starting may comprise restarting. Once started, the timer/counter may run. Running of the timer/counter may be associated with an occurrence. When the occurrence occurs, the value of the timer/counter may change (for example, increment or decrement). The occurrence may be, for example, an exogenous event (for example, a reception of a signal, a measurement of a condition, etc.), an endogenous event (for example, a transmission of a signal, a calculation, a comparison, a performance of an action or a decision to so perform, etc.), or any combination thereof. In the case of a timer, the occurrence may be the passage of a particular amount of time. However, it will be understood that a timer may be described and/or implemented as a counter that counts the passage of a particular unit of time. A timer/counter may run in a direction of a final value until it reaches the final value. The reaching of the final value may be referred to as expiration of the timer/counter. The final value may be referred to as a threshold. A timer/counter may be paused, wherein the present value of the timer/counter is held, maintained, and/or carried over, even upon the occurrence of one or more occurrences that would otherwise cause the value of the timer/counter to change. The timer/counter may be un-paused or continued, wherein the value that was held, maintained, and/or carried over begins changing again when the one or more occurrence occur. A timer/counter may be set and/or reset. As used herein, setting may comprise resetting. When the timer/counter sets and/or resets, the value of the timer/counter may be set to the initial value. A timer/counter may be started and/or restarted. As used herein, starting may comprise restarting. In some embodiments, when the timer/counter restarts, the value of the timer/counter may be set to the initial value and the timer/counter may begin to run.
As will be discussed in greater detail below, there are many different types of NF and each type of NF may be associated with a different set of functionalities. A plurality of different NFs may be flexibly deployed at different locations (for example, in different physical core network deployments) or in a same location (for example, co-located in a same deployment). A single NF may be flexibly deployed at different locations (implemented using different physical core network deployments) or in a same location. Moreover, physical core network deployments may also implement one or more base stations, application functions (AFs), data networks (DNs), or any portions thereof. NFs may be implemented in many ways, including as network elements on dedicated or shared hardware, as software instances running on dedicated or shared hardware, or as virtualized functions instantiated on a platform (e.g., a cloud-based platform).
For example, deployment 1410 comprises an additional network function, NF 1411A. The NFs 1411, 1411A may consist of multiple instances of the same NF type, co-located at a same physical location within the same deployment 1410. The NFs 1411, 1411A may be implemented independently from one another (e.g., isolated and/or independently controlled). For example, the NFs 1411, 1411A may be associated with different network slices. A processing system and memory associated with the deployment 1410 may perform all of the functionalities associated with the NF 1411 in addition to all of the functionalities associated with the NF 1411A. In an example, NFs 1411, 1411A may be associated with different PLMNs, but deployment 1410, which implements NFs 1411, 1411A, may be owned and/or operated by a single entity.
Elsewhere in
As shown in the figures, different network elements (e.g., NFs) may be located in different physical deployments, or co-located in a single physical deployment. It will be understood that in the present disclosure, the sending and receiving of messages among different network elements is not limited to inter-deployment transmission or intra-deployment transmission, unless explicitly indicated.
In an example, a deployment may be a ‘black box’ that is preconfigured with one or more NFs and preconfigured to communicate, in a prescribed manner, with other ‘black box’ deployments (e.g., via the interface 1490). Additionally or alternatively, a deployment may be configured to operate in accordance with open-source instructions (e.g., software) designed to implement NFs and communicate with other deployments in a transparent manner. The deployment may operate in accordance with open RAN (O-RAN) standards.
In example embodiments as depicted in
In existing technologies, the network may be substantially undifferentiated with respect to slice support. However, as new use cases emerge, it is possible that differentiation based on slice support increases. For example, as shown in
For example, when a wireless device (e.g., UE) moves into TA1, the UE may send a registration request to the network via TA1. In an example, the registration request may be based on reception of a system information block (SIB) received from a base station within the TA. The SIB may indicate that the base station is associated with the TA.
The registration request may indicate that the UE requests slice A and slice B. The registration request may be received by a mobility management function (e.g., AMF). The AMF may determine that requested slice A is supported by TA1. The AMF may send a registration accept indicating slice A. The registration accept may also indicate a registration area of the UE (e.g., comprise a tracking area list). The tracking area list may include TA1, because the registration request was received via TA1 and because TA1 supports a requested slice (slice A). The tracking area list may exclude TA2 because TA2 does not support slice A. The registration area may exclude TA3 because TA3 is not adjacent to TA1.
The UE may later move into TA2. Because the UE's registration area (registration area 1) does not include TA2, the UE may be forced to re-register (e.g., initiate/perform a registration update procedure). As shown in
The UE may later move into TA3. Because the UE's registration area (registration area 2) does not include TA3, the UE may be forced to re-register (e.g., initiate/perform a registration update procedure). As shown in
The example of
In the example of
The UE may later move to TA2. Because TA2 is in the UE's registration area (i.e., in the UE's TA list), there is no need for the UE to perform a registration update procedure. This helps to alleviate the problem of over-frequent registration update, but creates a new problem relating to paging.
The paging process may begin when the AMF receives an indication of data arrival for the UE (e.g., downlink data is available for the UE). For example, data may arrive at a user plane function (UPF, not shown), and the UPF notify the AMF that data has arrived. Based on the indication of data arrival, the AMF notifies network components (e.g., base stations, NG-RANs) within the UE's registration area (i.e., TA1, TA2, TA3). Upon receiving the respective notifications, the network components within the UE's registration area send paging messages for the UE within their respective coverage areas. Since the UE is in the coverage area of TA2, the paging message sent via TA2 is received by the UE.
However, suppose that the data is associated with a specific slice (e.g., slice A). In the example of
Accordingly, existing technologies are not prepared for the implementation of tracking areas which are differentiated with respect to slice support (e.g., support for different combination of network slices and/or network services). Network operators may reduce the frequency of registration updating in differentiated networks by relaxing the constraints on registration areas. For example, a single registration area may be allowed to include differentiated tracking areas which support different slices. However, while relaxation of this constraint can reduce over-frequent registration updates, it can cause other problems to arise, for example, in the context of paging. In particular, the network may receive data for a wireless device. The data may be associated with a particular slice. The network may page the wireless device via the tracking areas within the wireless device's registration area. But the registration area may include tracking areas that do not support the particular slice. As a result, the paging mechanisms may fail, or may lead to failed communication of the data.
Example embodiments of the present disclosure improve system performance by enhancing mechanisms for indicating data arrival. For example, a first network node may receive a first message from a second network node. The first message may indicate data arrival for a wireless device. The arrived data may be associated with a specific network service (e.g., slice). The first network node may select one or more access nodes which support the network service associated with the arrived data. For example, one or more other access nodes which do not support the network service may not be selected. The first network node may send a second message to the selected access node. The second message may indicate the data arrival for the wireless device. The sending of the second message is selective, based on the recipient's support for the network service. Accordingly, the pertinence of pages sent by selected access nodes may be increased. Moreover, access nodes which do not support the network service may not be selected and will therefore do not receive the second message. Accordingly, non-selected access nodes may send fewer wasteful pages.
As depicted in
As depicted in
In an example embodiment, Network Service information may comprise at least one or more of the following. Single Network Slice Selection Assistance Information (S-NSSAI): may identify a single network slice. Network Slice Selection Assistance Information (NSSAI): may identify a set of one or more S-NSSAI. Network Slice Group information: may identify a group of network slices. Data Network Name: may identify a data network associated with a network slice. Network Service identifier: may identify a network service. The network service may comprise a network slice. The Network Service Identifier may be an identifier of a network slice.
In an example embodiment, S-NSSAI may comprise at least one of following. Slice/Service Type (SST): may identify a type of network slice or a type of service supported by the network slice. Slice Differentiator (SD): may complement the SST to differentiate amongst multiple network slices of the same SST.
In the specification, a term of a NG-RAN may be interpreted as a base station, which may comprise at least one of a gNB, an eNB, a ng-eNB, a NodeB, an access node, an access point, an N3IWF, a relay node, a base station central unit (e.g., gNB-CU), a base station distributed unit (e.g., gNB-DU), and/or the like. In the specification, a term of an AMF may be interpreted as a core network device, which may comprise at least one of a mobility management function/entity, an access management function, and/or the like. In the specification a term of an SMF may be interpreted as a core network device, which may comprise at least one of a session management function/entity, a serving gateway, a PDN gateway, and/or the like.
In the specification, a term of a PDU session may be interpreted as a packet flow, which may comprise at least one of a QoS flow, a bearer, an EPS bearer, and/or the like.
In the specification, a network service may comprise one or more network slices. In an example, a first network service may comprise a first network slice. In an example, a second network service may comprise a second network slice. In an example, Network Service information may comprise one or more identifiers of one or more network services. In an example, the Network Service information may comprise one or more network slice identifiers (e.g., S-NSSAI, NSSAI, etc.) of one or more network slices associated with the network services. In an example, the Network Service information may comprise a first identifier of a first network service and/or a second identifier of a second network service. In an example, the Network Service information may comprise a first network slice identifier of a first network slice associated with the first network service and/or a second network slice identifier of a second network slice associated with the second network service.
In an example, based on the list of accepted network slices, the UE may establish one or more PDU sessions for one or more network slice in the list of accepted network slices. In an example, the one or more network slice may comprise the first network slice and/or the second network slice. In an example, the one or more PDU sessions may comprises the first PDU session and/or the second PDU session. In an example, the first PDU session may be associated with the first network slice and/or the second PDU session may be associated with the second network slice. To establish the one or more PDU sessions, the UE may send, to the AMF, one or more NAS messages comprising one or more PDU Session Establishment requests messages. The one or more PDU Session Establishment request messages may comprise one or more PDU Session ID for one or more PDU sessions and/or information on one or more network slices associated with the one or more PDU sessions. The AMF may receive the one or more NAS messages comprising the one or more PDU Session Establishment request messages. The AMF may select one or more SMFs for the one or more PDU Session Establishment request messages. The AMF may invoke to the one or more selected SMFs, one or more service requests (e.g., Nsmf_PDUSession_CreateSMContext request) comprising the one or more PDU Session Establishment request messages. After configuring network resources for the one or more PDU sessions based on the one or more PDU Session Establishment requests, the one or more SMF may send one or more service responses to the AMF. The one or more service responses to the AMF may comprise one or more PDU Session Establishment accept messages. Based on the one or more service responses from the one or more SMFs, the AMF may deliver the one or more PDU Session Establishment accept messages to the UE. The AMF may update UE Context in AMF based on the one or more responses from the one or more SMFs
In an example, after establishing the one or more PDU sessions comprising the first PDU session and/or the second PDU session, the UE may transition from an RRC connected state and/or an RRC inactive state to an RRC idle state. After transitioning to the RRC idle state, the UE may camp on a cell belonging to the second TA and the UE may monitor paging message via a paging channel in the cell belonging to the second TA. The UE may select and/or camp on the cell of the second TA, based on that a signal quality of the cell belonging to the second TA is better than a signal quality of a cell belonging the first TA.
In an example, a UPF managing the second PDU session of the UE may receive an incoming data for the UE. For the incoming data, the UPF may send indication of data arrival to a SMF. For example, the indication of data arrival may be a Data Notification message. The Data Notification message may comprise QoS flow identification information. The SMF may send the UPF with Data Notification Ack message to acknowledge the reception of the Data Notification message. To indicate the data arrival to the AMF, the SMF may invoke a service session request (e.g., Namf_Communication_N1N2MessageTransfer) to the AMF. The service session request (e.g., Namf_Communication_N1N2MessageTransfer) may comprise SUPI, PDU Session ID, N1 SM container, N2 SM information (QFI(s), QoS profilc(s), CN N3 Tunnel Info and/or S-NSSAI), Paging Policy Indicator, 5QI, N1N2TransferFailure Notification Target Address, Area of validity for N2 SM information, ARP and/or Extended Buffering support. The SUPI may identify a UE associated with the data arrival. The PDU Session ID may identify a PDU session associated with the data arrival. The N1 SM Container may comprise a message which the SMF may send to the UE to control the PDU session. The N1 SM Container may be a message between the SMF and the UE, using Session Management layer protocol. The AMF may not decode the N1 SM Container. The N2 SM information may comprise a message that the SMF sends to a NG-RAN, to control a N3 interface and the PDU session. The N2 SM Container is a message between the SMF and the NG-RAN, and the AMF may not decode the N2 SM information. The Paging Policy Indicator may identify which paging policy may be applied. For example, a paging policy may indicate how fast repetition of paging may be done when there is no response to the paging from the UE. The N1N2TransferFailre Notification Target Address may indicate where the AMF may contact when the service session request (e.g., Namf_Communication_N1N2MessageTransfer) fails. The Area of validity for N2 SM information may indicate an area where the N2 SM information can be delivered to. The ARP may indicate an ARP value associated with the N2 SM information. The Extended Buffering support may indicate whether an extended buffering is supported or not.
In an example, when the AMF receives the service session request (e.g., Namf_Communication_N1N2MessageTransfer request) from the SMF, the AMF may identify Network Service information associated with the service session request (e.g., Namf_Communication_N1N2MessageTransfer request). For example, the Network Service information may comprise information on a network service associated with the service session request (e.g., Namf_Communication_N1N2MessageTransfer), information on a network slice associated with the Service session request (e.g., Namf_Communication_N1N2Message Transfer) and/or the PDU session associated with the service session request (e.g., Namf_Communication_N1N2MessageTransfer). For example, the Network Service information may comprise information on a network service associated with the data arrival, information on a network slice associated with the data arrival and/or the PDU session associated with the data arrival.
Based on the identified Network Service information, the AMF may determine one or more TAs, from a list of TAIs associated with a registration area for the UE. The AMF may determine the one or more TAs from the list of TAIs, based on that the one or more TAs support the network service indicated by the Network Service information.
In an example, the AMF may send one or more N2 Paging messages to one or more NG-RANs supporting the determined one or more TAs. The determined one or more TAs support the indicated network service. In an example, the AMF may not send one or more N2 Paging messages to one or more NG-RANs not supporting the determined one or more TAs. In an example, if one or more NG-RANs do not support the indicated network service, the AMF may not send one or more N2 Paging messages to the one or more NG-RANs. For example, because the second NG-RAN supports the second TA supporting the second network slice associated with the data arrival, the AMF may send a N2 paging message of the one or more N2 paging messages to the second NG-RAN. For example, because the first NG-RAN does not support a TA supporting the second network slice associated with the data arrival, the AMF may not send to the first NG-RAN, a N2 Paging message of the one or more N2 Paging messages.
The one or more N2 Paging messages may comprise at least one of NAS ID for paging, Registration Arca list, Paging DRX length, Paging Priority, Access associated to the PDU Session, Network Service information, Enhanced Coverage Restricted information and/or WUS Assistance information. The NAS ID for paging may indicate the identity of the UE to which the arrived data is delivered. The Paging DRX length may indicate a time interval/duration in which the UE monitors paging channel over the Uu interface. The Paging Priority may indicate whether the paging for the UE is prioritized than a paging for other UEs. The Access associated to the PDU session may indicate whether the UE may use 3GPP access or Non-3GPP access when the UE responds to the paging. The Network service information may indicate a network service associated with the data arrival indicated by the received Service session request (e.g., Namf_Communication_N1N2MessageTransfer). The Registration Area list may indicate a list of TAIs associated with a registration area for the UE. The Enhanced Coverage Restricted information may indicate whether enhanced coverage applies or not. The WUS Assistance information may indicate information related to WUS operation.
In an example embodiment, in the Registration Area list of the one or more N2 paging messages, the AMF may include one or more TAs in the list of TAIs associated with a registration area for the UE. In other example, in the Registration Area list of the one or more N2 paging messages, the AMF may include one or more TAs supporting the network service indicated by the Network Service information, among TAs in the list of TAIs associated with a registration area for the UE. In an example, in the Registration Arca list of the one or more N2 paging messages, the AMF may not include one or more TAs not supporting the network service indicated by the Network Service information, among the TAs in the list of TAIs associated with a registration area for the UE. In an example, the AMF may include all TAs in the Registration Area list of the one or more N2 paging messages, among the TAs in the list of TAIs associated with a registration area for the UE.
In an example, when the one or more NG-RANs receive the one or more N2 paging messages from the AMF, the one or more NG-RANs may send one or more paging messages via one or more cells of the one or more TAs indicated by the Registration Arca list. In an example, the one or more NG-RANs may send the one or more paging messages, via the one or more cells supporting the network service indicated by the Network Service information, among the one or more cells belonging to one or more TAs in the list of TAIs indicated by the Registration Area list. The one or more NG-RANs may not send one or more paging messages via one or more cells not supporting the network service indicated by the Network Service information, among one or more cells belonging to one or more TAs in the Registration Area list. The one or more paging messages sent via the one or more cells may comprise information on an identity of UE associated with the data arrival and/or the Network Service information associated with the data arrival.
In an example, an RRC entity of the UE may receive a paging message of the one or more paging messages, via the cell of the one or more NG-RANs. The RRC entity of the UE may determine whether an identity of UE in the received paging message matches an identity of the UE. If the identity of UE in the received paging message matches the identity of the UE, the RRC entity of the UE may indicate, to a NAS entity of the UE, a reception of a paging. If the received paging message comprises Network Service information, the RRC entity may deliver the Network Service information to the NAS entity. After receiving indication of reception of a paging from the RRC entity, the NAS entity of the UE may determine whether the network service indicated by the Network Service information is allowed for the UE. For example, the NAS entity of the UE may determine whether the list of allowed network slices comprises the network service indicated by the Network Service information. In an example, if the NAS entity determines that the network service indicated by the Network Service information is allowed for the UE, the NAS entity of the UE may perform (e.g., initiate) a service request procedure. For example, if the NAS entity determines that the network slice indicated by the Network Service information is in the list of allowed network slice for the UE, the NAS entity of the UE may perform a service request procedure. In an example, if the NAS entity determines that the network service indicated in the Network Service information is not allowed, the NAS entity of the UE may not perform a service request procedure. For example, if the NAS entity determines that the network slice indicated by the Network Service information is not in the list of allowed network slices, the NAS entity of the UE may not perform a service request procedure. In an example, if the NAS entity determines that the network service indicated by the Network Service information is not allowed, the NAS entity of the UE may send a NAS message to the AMF, to report an error. The error may indicate that the UE is paged for a network service which is not allowed for the UE.
In an example embodiment as depicted in
In an example, after receiving the service session request (e.g., Namf_Communication_N1N2MessageTransfer) from the SMF, the AMF may determine one or more first TAs not supporting the network service indicated by a Network Service Information associated with the data arrival, among one or more TAs in a list of TAIs associated with a registration area for the UE. In an example, the AMF may determine one or more second TAs supporting the network service indicated by the Network Service Information associated with the data arrival, among the one or more TAs in the list of TAIs associated with a registration area for the UE. In an example, after determining the one or more first TAs and/or the one or more second TAs, the AMF may determine one or more first NG-RANs and/or one or more second NG-RANs. The one or more first NG-RANs may support the one or more first TAs and/or may not support the one or more second TAs. The one or more second NG-RANs may not support the one or more first TAs and/or may support the one or more second TAs. Based on the determined one or more first NG-RANS and/or one or more second NG-RANs, the AMF may send one or more first N2 paging messages to the one or more first NG-RANs and/or one or more second N2 paging messages to the one or more second NG-RANs. The one or more first N2 paging messages may comprise the Network Service information and/or the one or more second N2 paging messages may not comprise the Network Service information
For example, the Network Service information associated with the data arrival may indicate a second network slice. A first TA may not support the second network slice and a second TA may support the second network slice. If one or more second NG-RANs support the second TA, the AMF may send one or more second N2 paging messages to the one or more second NG-RANs. The one or more second N2 paging messages may comprise NAS ID (e.g., identifier of the UE) for paging and/or Registration Area list and/or Paging DRX length and/or Paging Priority and/or access associated to the PDU Session. The one or more second N2 Paging messages sent to the one or more second NG-RAN may not comprise Network Service information. If one or more first NG-RANs do not support the second TA and/or support the first TA, the AMF may send one or more first N2 paging messages to the one or more first NG-RANs. The one or more first N2 paging messages may comprise NAS ID (e.g., identifier of the UE) for paging and/or Registration Area list and/or Paging DRX length and/or Paging Priority and/or access associated to the PDU Session and/or Network Service information.
For example, after receiving the service session request (e.g., Namf_Communication_N1N2MessageTransfer) from a SMF for a data arrival, an AMF may send a first N2 Paging message to a first NG-RAN not supporting a network slice associated with the data arrival. The AMF may send a second N2 Paging message to a second NG-RAN supporting the network slice associated with the data arrival. The first N2 Paging message may comprise Network Service information and/or the second N2 Paging message may not comprise the Network Service information. By selectively including the Network Service information, signaling resource over N2 interface and Uu interface may be used efficiently.
After receiving the one or more N2 paging messages, the one or more NG-RANs may send one or more paging message via one or more cells, based on the information in the one or more received N2 paging messages. For example, after receiving the one or more first N2 paging messages, one or more first NG-RANs may send one or more first paging messages via cells. The one or more first paging messages may comprise the Network Service information. For example, after receiving one or more second N2 paging messages, the one or more second NG-RANs may send one or more second paging messages via cells. The one or more second paging messages may not comprise the Network Service information.
In an example, a UE may receive a first paging message or a second paging message, depending on a cell where the UE camps on.
In an example, the UE may receive the first paging message from the cell belonging to the first NG-RAN which may not support the network service associated with the data arrival. The first paging message may comprise the Network Service information. The Network Service information may comprise an information on the network service associated with the data arrival and/or the information of the network slice associated with the data arrival. When the UE receives the first paging message, the UE may determine that there is an arrived data for the network service indicated by the Network Service information. When the UE determines that the cell where the UE camps on does not support the network service indicated by the Network Service information, the UE may perform cell reselection to a cell supporting the network service indicated by the Network Service information. After the cell reselection, the UE may perform a service request procedure to respond to the received paging message.
In an example, a UE may receive the second paging message via the cell belonging to the second NG-RAN supporting the network service associated with the data arrival. The second paging message may not comprise the Network Service information. When the UE receives the second paging message, the UE may determine that there is an arrived data for the UE. The UE may perform a service request procedure to respond to the received paging message.
In an example embodiment as depicted in
In an example, when the AMF receives the service session request (e.g., Namf_Communication_N1N2MessageTransfer) request from the SMF, the AMF may identify Network Service information. The Network Service information may comprise an information on a network service associated with the received service session request (e.g., Namf_Communication_N1N2MessageTransfer request) and/or information on a network slice associated with the received service session request (e.g., Namf_Communication N1N2Message Transfer request). For the received service session request (e.g., Namf_Communication_N1N2MessageTransfer), the AMF may send one or more N2 paging messages to one or more NG-RANs. The one or more N2 Paging message may comprise NAS ID (e.g., identifier of the UE) for paging and/or Registration Area list and/or Paging DRX length and/or Paging Priority and/or access associated to the PDU Session and/or the Network Service information.
In an example, a first NG-RAN of the one or more NG-RAN may receive the one or more N2 Paging messages from the AMF. The one or more N2 Paging messages may comprise the Network Service information. The first NG-RAN may identify that the first NG-RAN may not support a network service indicated by the Network Service information, in one or more TAs that the first NG-RAN manages. Based on the identification, the first NG-RAN may determine that the first NG-RAN does not send one or more paging messages via the one or more TAs where the network service is not supported. In an example, a second NG-RAN of the one or more NG-RAN may receive the one or more N2 Paging messages from the AMF. The one or more N2 Paging message may comprise the Network Service information. The second NG-RAN may identify that the second NG-RAN supports the network service indicated by the Network Service information, in one or more TAs that the second NG-RAN manages. The second NG-RAN may determine that it sends one or more paging messages over the one or more TAs that the network service indicated by the Network Service information are supported. The one or more paging messages that the second NG-RAN send may comprise an identity of the UE and/or the Network Service Information.
In an example embodiment as depicted in
In an example, the one or more NG-RANs may receive the one or more N2 Paging message from the AMF. The one or more N2 Paging message may comprise the Network Service information. Cells that the one or more NG-RANs manage may comprise one or more first cells and/or one or more second cells. Among the one or more first cells and/or the one or more second cells, the one or more NG-RANs may determine the one or more second cells that support the network service indicated by the Network Service information. For example, the one or more second cells may support the second TA and/or may support the second network slice and/or may not support the first TA and/or may not support the first network slice. Based on determining the one or more second cells, the one or more NG-RANs may transmit one or more paging messages in the determined one or more second cells. The one or more paging messages may comprise the Network Service information. Among the one or more first cells and/or the one or more second cells, the one or more NG-RANs may determine the one or more first cells that may not support the second network service. For example, the one or more first cells may support the first network slice and/or may support the first TA and/or may not support the second TA and/or may not support the second network slice. Based on determining the one or more first cells, the one or more NG-RANs may not transmit one or more paging messages in the determined one or more first cells.
In an example embodiment as depicted in
In an example embodiment as depicted in
In the example embodiments as depicted in
In an example, the OAM system may configure one or more gNB-DUs. The OAM system may configure the one or more gNB-DUs to support one or more network slices and/or to support one or more network services. The OAM system may configure the one or more gNB-DUs with information of one or more TAs that the one or more gNB-DUs support. The OAM system may configure the one or more gNB-DUs with information of one or more gNB-CUs to which the one or more gNB-DUs establish connection.
In an example, the OAM system may configure one or more gNB-CUs. The OAM system may configure the one or more gNB-CUs to support one or more network slices and/or one or more network services. The OAM system may configure the one or more gNB-CUs with information of which one or more TAs the one or more gNB-CUs belong to. The OAM system may configure the one or more gNB-CUs with information of one or more AMFs to which the one or more gNB-CUs may establish connection.
In an example, based on the information configured by the OAM system, the one or more gNB-CUs may establish connection with the one or more AMFs. The one or more gNB-DUs may establish connection with the one or more gNB-CUs.
For example, the one or more gNB-DUs may perform one or more F1 Setup procedures with one or more gNB-CUs, based on the information configured by the OAM system. The one or more F1 Setup Request messages may comprise at least one of the following. gNB-DU ID: may identify the gNB-DU. gNB-DU Name: may identity the name of the gNB-DU. gNB-DU Served cells: may indicate list of cells supported by the gNB-DU. For each cell in the list, may further comprise NR CGI, 5GS TAC and/or TA1 Slice Support List. The NR CGI may indicate global cell identity of a cell. The 5GS TAC may indicate a TA code of the cell. The TA1 slice support list may comprise a list of supported network slices for the cell. Transport Layer Address Info: may indicate link identifier to contact the gNB-DU.
In an example, the one or more gNB-CUs may receive the one or more F1 Setup Request messages from one or more gNB-DUs. The one or more gNB-DUs may comprise one or more first gNB-DUs and/or one or more second gNB-DUs. The one or more gNB-CUs may store the information of the one or more F1 Setup Request messages, received from the one or more gNB-DUs. The one or more gNB-CUs may use the stored information, when the one or more gNB-CUs determine to which one or more gNB-DUs one or more F1 paging messages are sent. For example, the one or more first gNB-DUs may send to one or more gNB-CUs, one or more first F1 Setup Request messages. The one or more first F1 Setup Request messages may indicate that the one or more first gNB-DUs support a first network slice. For example, the one or more second gNB-DUs may send to one or more gNB-CUs, one or more second F1 Setup Request messages. The one or more second F1 Setup Request messages may indicate that the one or more second gNB-DUs do not support a first network slice.
In an example, the one or more gNB-CUs may receive from an AMF, one or more N2 paging messages. The one or more N2 paging messages may comprise Network Service information. The Network Service information may indicate a first network service. The first network service may be a first network slice. Based on the one or more first F1 Setup Request messages, for the received one or more N2 Paging messages, the one or more gNB-CUs may send one or more F1 paging messages to the one or more first gNB-DUs. Based on the one or more second F1 Setup Request messages, for the one or more N2 paging messages, the one or more gNB-CU may not send one or more F1 paging messages to the one or more second gNB-DU.
In an example, one or more gNB-CUs may send one or more NG Setup Requests to an AMF. The one or more NG Setup Request messages to an AMFs may comprise at least one of the following. Global RAN Node ID: may identify the gNB-CU. RAN Node Name: may identify the name of the gNB-CU. Supported TA List: may be a list of TAs supported by the gNB-CU. For each TA, the Supported TA List may further comprise, TAC and/or TA1 Slice Support List. The TAC may indicate a TA code for the TA. The TA1 Slice Support List may be a list of network slices supported by the TA.
The AMF may receive the one or more NG Setup Request messages from the one or more gNB-CUs. The AMF may store the information of the one or more NG Setup Request messages, sent by the one or more gNB-CUs. The AMF may use the stored information when the AMF may determine the one or more gNB-CUs to which one or more N2 paging messages are delivered. For example, the one or more gNB-CUs may comprise one or more first gNB-CUs and/or one or more second gNB-CUs. The one or more first gNB-CUs may send one or more first NG Setup Request messages. The one or more second gNB-CUs may send one or more second NG Setup Request messages. The one or more first NG Setup Request messages may comprise an indication of support for first network service. The first network service may be a first network slice. The one or more second NG Setup Request messages may comprise an indication for second network service. The second network service may be a second network slice.
When the AMF receives one or more Service session request (e.g., Namf_Communication_N1N2MessageTransfer) indicating a data arrival for a first network service, the AMF may determine one or more gNB-CUs to which one or more N2 paging messages are sent. Based on the stored information that the one or more first gNB-CUs support the first network service, the AMF may determine to send one or more N2 paging messages to the one or more first gNB-CUs. The one or more first N2 paging messages may comprise Network Service information. The Network Service information may comprise information of a first network service. The first network service may be a first network slice. Based on the stored information that the one or more second gNB-CUs do not support the first network service, the AMF may determine not to send one or more N2 paging messages to the one or more second gNB-CUs.
In the example embodiments as depicted in
In an example, an OAM system may configure a NSSF with one or more Assistance information on network service. For example, an Assistance information on network service may comprise one or more of the following. Information of NG-RAN: may comprise an identity of a NG-RAN and/or list of supported network slices by the NG-RAN and/or list of supported TAs by the NG-RAN and/or list of supported network services by the NG-RAN. Information of network slice: may comprises an identity of a network slice and/or a list of NG-RANs supporting the network slice and/or a list of TAs supporting the network slice. Information of network service: may comprises an identity of a network service and/or a list of NG-RANs supporting the network service, and/or a list of TAs supporting the network service. Information on TA: may comprise an identity of a TA and/or list of supported network slices by the TA and/or list of NG-RANs supporting the TA.
In an example, the OAM system may configure a NRF with one or more Assistance information of network service. For example, an Assistance information may comprise at least one of the following. Information of NG-RAN: may comprise an identity of a NG-RAN and/or supported network slices by the NG-RAN and/or list of supported TAs by the NG-RAN and/or list of supported network services by the NG-RAN. Information of network slice: may comprises an identity of a network slice and/or a list of NG-RANs supporting the network slice, and/or a list of TAs supporting the network slice. Information of network service: may comprises an identity of a network service and/or a list of NG-RANs supporting the network service, and/or a list of TAs supporting the network service. Information of TA: may comprise an identity of the TA and/or list of supported network slices by the TA and/or list of NG-RANs supporting the TA.
In an example, the OAM system may configure a PCF with one or more Assistance information on network service. For example, an Assistance information may comprise at least one of the following. Information of paging strategy: may comprise information of whether an AMF may send one or more paging messages in TAs in a list of TA1 associated with a registration area for a UE and/or whether the AMF may send one or more paging messages in TAs supporting the network slice/service associated with data arrival, among TAs in the list of TA1 associated with a registration area for the UE. Information of NG-RAN: may comprise an identity of a NG-RAN and/or list of supported network slices by the NG-RAN and/or list of supported TAs by the NG-RAN and/or list of supported network services by the NG-RAN. Information on network slice: may comprises an identity of a network slice and/or a list of NG-RANs supporting the network slice, and/or a list of TAs supporting the network slice. Information on network service: may comprises an identity of a network service and/or a list of NG-RANs supporting the network service, and/or a list of TAs supporting the network service. Information on TA: may comprise an identity of the TA and/or list of supported network slices by the TA and/or list of NG-RANs supporting the TA.
In an example, AMF may invoke one or more entry requests (e.g., Nnrf_NFManagement_NFRegister Request) to a NRF. An entry request (e.g., Nnrf_NFManagement_NFRegister Request) may comprise information related to information related to a TA and/or information related to a NG-RAN and/or information related to a network service.
In an example, the information related to a network service may comprise at least one of the following. Information of a network service/slice for which the entry request (e.g., Nnrf_NFManagement_NFRegister Request) is associated. Information of one or more network services/slices for which a UE is allowed. Information of one or more network services/slices for which the UE has one or more established PDU sessions.
In an example, the information related to a TA may comprise at least one of the following. Information of a list of TAIs associated with a registration area of the UE. Information of current TA where the UE is in. Information of a list of TAs where the network service associated with the information related to a network service is supported.
In an example, the information related to a NG-RAN may comprise at least one of the following. Information of one or more network services supported by the NG-RAN. A list of one or more TAs supported by the NG-RAN. A current NG-RAN to which the UE is connected to.
When the NRF receives the entry request (e.g., Nnrf_NFManagement_NFRegister Request) from the AMF, the NRF stores information of the entry request in its storage. The NRF may use the stored information, when the NRF receives an information query from a network node.
In an example, an AMF may receive a service session request (e.g., Namf_Communication_N1N2MessageTransfer) from a SMF associated with a data arrival at UPF. To determine a target paging area where one or more paging messages are sent, the AMF may invoke a discovery request (e.g., Nnssf_Paging_Area Request message and/or the like). The discovery request (e.g., the Nnssf_Paging_Area Request message and/or the like) may comprise information of a network service/slice associated with the data arrival and/or Network Service information associated with the data arrival. In response to the discovery request (e.g., Nnssf_Paging_Area Request and/or the like), the NSSF may respond to the AMF with information related to a paging. For example, the information related to a paging from the NSSF may comprise a list of target TAs where one or more paging messages are sent and/or a list of target NG-RANs by which the one or more paging messages are sent and/or an indication of whether the one or more paging message may be sent in all TAs in a list of TA1 associated with a registration area for the UE. Based on the response from the NSSF, the AMF may send one or more N2 paging messages to one or more NG-RANs in the list of target NG-RANs and/or to one or more NG-RANs supporting one or more TAs in the list of target TAs.
In another example, to decide where one or more paging messages are sent, an AMF may invoke Nnrf_NFDiscovery Request message and/or the like toward a NRF after receiving service session request (e.g., Namf_Communication_N1N2MessageTransfer) from SMF associated with a data arrival at UPF. The Nnrf_NFDiscovery Request message and/or the like may comprise Network Service information associated with the data arrival and/or an indication that the AMF requests information of a paging target area where one or more paging messages are sent. In response to the Nnrf_NFDiscovery Request message and/or the like, the NRF may respond to the AMF with Nnrf_NFDiscovery Response message and/or the like. Nnrf_NFDiscovery Response message and/or the like may comprise a list of target TAs where one or more paging messages are sent and/or a list of target NG-RANs by which one or more paging messages are sent and/or an indication that one or more paging messages are sent to all TAs in a list of TA1 associated with a registration area for the UE. Based on the response from the NRF, the AMF may send one or more N2 paging messages to one or more NG-RANs in the list of target NG-RANs and/or to one or more NG-RANs supporting one or more TAs in the list of target TAs.
In an example, if the Nnrf_NFDiscovery Response message and/or the like indicates that the one or more paging messages are sent to all TAs in the list of TA1 associated with a registration area for the UE, the AMF may send one or more N2 paging messages to the all NG-RANs supporting one or more TAs in the list of TA1 associated with a registration area for the UE.
In another example, an AMF may invoke Npcf_UEPolicyControl_Create request and/or the like to a PCF, to get policy information of paging handling at the AMF. The Npcf_UEPolicyControl_Create request and/or the like may comprise information of Network Service information associated with a UE. In response to the Npcf_UEPolicyControl Create request and/or the like, the PCF may respond with Npcf_UEPolicyControl_Create response and/or the like to the AMF. The response from the PCF may comprise indication that one or more paging messages may be sent to all TAs in a list of TA1 associated with a registration area for the UE. If the Npcf_UEPolicyControl_Create response and/or the like indicates that one or more paging messages may be sent to all TAs in the list of TA1 associated with registration area for the UE, the AMF may send one or more N2 paging messages to all NG-RANs supporting the one or more TAs in the list of TA1 associated with registration area for the UE.
In an example embodiment as depicted in
In an example, when a NG-RAN performs NG Setup procedure to an AMF, to setup a connection between the NG-RAN and the AMF, the AMF may update its context to store the information of the NG-RAN. For example, when the AMF update its context, the AMF may store an identity of the NG-RAN and/or a list of TA1 supported by the NG-RAN and/or a list of network slices supported by the NG-RAN and/or a list of network service supported by the NG-RAN.
In an example, when the UE camps on a cell, the UE may send a registration request message to the AMF via the NG-RAN. The registration request message may comprise a list of requested network slices. When the registration request message is received, the AMF may send to a UDM, a request for information of one or more subscribed network slices of the UE. The UDM may respond to the AMF, with information of the list of subscribed network slices of the UE. When the AMF receives the response from the UDM, the AMF may contact a NSSF to request a list of allowed network slices of the UE. The request to the NSSF may comprise the list of requested network slices and/or the list of subscribed network slices of the UE. In response to the request from the AMF, the NSSF may respond to the AMF with information of the list of allowed network slices. Based on the list of allowed network slice, the AMF may send the list of allowed network slice to the UE via a registration accept message and/or the AMF may store the information on the list of allowed network slices in the UE context in AMF. The UE context in AMF may comprise following information:
After receiving the list of allowed network slices from the AMF, to use data service, the UE may perform a procedure to establish of one or more PDU session for one or more network slices. To establish the one or more PDU sessions, the UE may send one or more NAS messages to the AMF. The one or more NAS messages may comprise one or more PDU Session Establishment Request messages. The one or more NAS messages may comprise S-NSSAI, UE Requested DNN, PDU Session ID and/or N1 SM Container. The S-NSSAI may indicate a network slice within which a PDU session is established. The UE Requested DNN may identify a data network to which the PDU session is connected. The PDU Session ID may identify the PDU session which is established. The N1 SM Container may be a message between the UE and the SMF and may encapsulate the PDU Session Establishment Request message. The AMF may not decode the S1 SM Container. When the AMF receives the one or more NAS messages, the AMF may deliver one or more S1 SM Containers of the one or more NAS messages to one or more SMFs. In response to the one or more PDU Session Establishment requests of the one or more S1 SM Containers, the one or more SMFs may perform network resource configuration and may compose one or more PDU Session Establishment Accept messages. The one or more SMFs may trigger one or more service session requests (e.g., Namf_Communication_N1N2MessageTransfer) to the AMF. The one or more service session requests (e.g., Namf_Communication_N1N2Message Transfer) may comprise one or more PDU Session IDs and/or one or more N2 SM Information and/or one or more N1 SM Containers. The one or more N1 SM Containers may be one or more messages between the UE and the one or more SMFs. The one or more N1 SM Containers may comprise the one or more PDU Session Establishment Accept messages. When the AMF receives the one or more service session requests (e.g., Namf_Communication_N1N2MessageTransfer) from the one or more SMFs, the AMF may send the UE with one or more NAS messages. The one or more NAS messages may comprise the one or more N1 SM Container. When the AMF receives the one or more service session requests (e.g., Namf_Communication_N1N2MessageTransfer) from one or more SMFs, the AMF may update the UE Context in AMF. For example, to update the UE Context in AMF, the AMF may store information of the one or more service session request (e.g., Namf_Communication_N1N2MessageTransfer), excluding information of one or more N1 SM Containers and/or one or more N2 SM Information. For example, the one or more N1 SM Containers are for communication between the UE and the one or more SMFs. For example, the one or more N2 SM information are for communication between one or more NG-RANS and the one or more SMFs. For example, the stored information may comprise the one or more PDU session IDs for one or more PDU sessions and/or one or more information of network services associated with one or more PDU sessions and/or one or more information on the network slices associated with one or more PDU sessions.
In an example, after the one or more PDU sessions are established, a SMF of the one or more SMFs may trigger service session request (e.g., Namf_Communication_N1N2Message Transfer) to the AMF when a data for the UE arrives at a UPF. In the service session request (e.g., Namf_Communication_N1N2Message Transfer), the SMF may include the PDU session ID associated with the arrived data at the UPF. When the AMF may receive service session request (e.g., Namf_Communication_N1N2Message Transfer) from the SMF, the AMF may identify the PDU session ID of the service session request (e.g., Namf_Communication_N1N2MessageTransfer). Based on the identified PDU session ID and/or based on the UE context in AMF, the AMF may determine the network service associated with the arrived data. Based on the determined network service, the AMF may construct Network Service information. To construct the Network Service information, for example, the AMF may determine whether the PDU session ID in service session request (e.g., Namf_Communication_N1N2MessageTransfer) exists in the UE context in AMF. When the PDU session ID exists in the UE context in AMF, the AMF may identify information of a network service associated with the PDU session ID. For example, the network service may be a network slice. After identifying information on the network service, the AMF may map the PDU Session ID included in the service session request (e.g., Namf_Communication_N1N2MessageTransfer) to the Network Service information. The AMF may use the Network Service information as described in the
In an example embodiment as depicted in
In an example, when there is a data arrival for the UE at UPF, the SMF may receive a Data Notification message from the UPF. When the SMF receives the Data Notification message, the SMF may determine Network Service information associated with the data arrival, using the stored information. The Network Service information may comprise information of the network slice associated with the arrived and/or information of the network service associated with the arrived data. To indicate the data arrival, the SMF may invoke service session request (e.g., Namf_Communication_N1N2MessageTransfer) to AMF. The service session request (e.g., Namf_Communication_N1N2MessageTransfer) may comprise the Network Service Information. When the AMF receives the service session request (e.g., Namf_Communication_N1N2MessageTransfer) comprising the Network Service information, the AMF may determine the one or more TAs to which one or more paging messages are delivered. The AMF may determine the one or more NG-RANs to which one or more N2 paging messages are delivered, as described in the example of
In an example, a data for the UE in RRC inactive state may arrive at the UPF. For the UE in RRC inactive state, the UPF may send the data to the gNB-CU-UP. When the gNB-CU-UP receives the data from the UPF, the gNB-CU-UP may determine at least one of a PDU session associated with the data and/or a network slice associated with the data and/or information on a network service associated with the data. After determining at least one of a PDU session associated with the data and/or a network slice associated with the data and/or the information on network service associated with the data, the gNB-CU-UP may send a DL Data Notification message to the first gNB-CU-CP to indicate the arrival of a data. The DL Data Notification message may comprise Network Service information. The Network Service information may comprise at least one of the determined PDU session information and/or the determined associated network slice information and/or the determined information on network service. For example, the DL Data Notification message may indicate that the arrived data is for a second PDU session and/or the second network slice and/or a second network service. After receiving the DL Data Notification message from the gNB-CU-UP, the first gNB-CU-CP may determine which gNB-CU-CPs in the RAN notification area support the network service and/or the network slice and/or the PDU session indicated in the Network Service information. For example, the first gNB-CU-CP may determine that the second gNB-CU-CP may not support the second network slice. The first gNB-CU-CP may not send a RAN Paging message to the second gNB-CU-CP. For example, the first gNB-CU-CP may determine that the third gNB-CU-CP may support the second network slice. The first gNB-CU-CP may send RAN Paging message to the third gNB-CU-CP. The RAN Paging message to the third gNB-CU-CP may comprise the Network Service Information associated with the arrived data. When the third gNB-CU-CP receives the RAN Paging message, the third gNB-CU-CP may send paging messages via one or more cells of the third gNB-CU-CP. If the UE receives the paging message, the UE may send a response message.
In another example, when a gNB-CU-CP transits a UE into RRC inactive state, the gNB-CU-CP may determine a RAN notification area for the UE. When the gNB-CU-CP determines the RAN notification area for the UE, the gNB-CU-CP may identify the Network Service information for an active PDU session. Based on the Network Service information for the active PDU session, the gNB-CU-CP may identify one or more neighboring gNB-CU-CPs that may support a network service indicated by the Network Service information. Based on the information on the identified neighboring gNB-CU-CPs that may support the network service, the gNB-CU-CP may include in the RAN notification area, the area managed by the neighboring gNB-CU-CPs supporting the network service. The gNB-CU-CP may send an RRC release message to the UE, comprising the RAN notification area.
In an example, an AMF may receive from a SMF, a message indicating a data arrival for the UE. The AMF may select one or more NG-RANs supporting a network service associated with the data arrival for the UE, among one or more NG-RANs supporting one or more TAs in the list of TAIs associated with registration area of the UE. The AMF may send one or more N2 Paging messages, to the one or more NG-RANs supporting the network service associated with the data arrival.
In an example, when an AMF sends one or more first N2 paging messages to one or more first NG-RANs, the AMF may start a retransmission timer. The retransmission timer may be used to determine when the AMF resends one or more N2 paging messages in a wider area. For example, when the retransmission timer expires, and if the AMF does not receive a response from a UE, the AMF may send one or more second N2 paging messages to one or more second NG-RANs. The one or more second N2 paging messages may indicate the data arrival for the UE. The one or more second NG-RANs may comprise one or more first NG-RANs and/or other one or more NG-RAN than the one or more first NG-RANs.
In an example, a NG-RAN may receive from an AMF, a message indicating a data arrival for the UE. The NG-RAN may select one or more cells supporting a network service associated with the data arrival for the UE, among one or more cells supporting one or more TAs in the list of TAIs associated with registration area of the UE. The NG-RAN may send one or more paging messages, via the one or more cells supporting the network service associated with the data arrival.
In an example, a gNB-CU may receive from an AMF, a message indicating a data arrival for the UE. The gNB-CU may select one or more gNB-DUs supporting a network service associated with the data arrival for the UE, among one or more gNB-DUs supporting one or more TAs in the list of TAIs associated with registration area of the UE. The gNB-CU may send one or more F1 Paging messages, to the one or more gNB-DUs supporting the network service associated with the data arrival.
In example embodiments, a first network node (e.g., AMF) may receive a first message (e.g., Namf_Communication_N1N2MessageTransfer) from a second network node (e.g., SMF). The first message may indicate an arrival of data for a UE. For the received first message, the first network node may select an access node (e.g., NG-RAN) among one or more access nodes, based on a network service. For example, the network service may support the transport of the data. For the selected access node, the first network node may send a second message (e.g., N2 paging message) to the selected access node. For example, the second message may indicate the data arrival of the UE.
In an example, the first network node may determine whether an access node supports the network service associated with the arrived data. If the access node supports the network service associated with the arrived data, the first network node may select the access node. The first network node may send to the selected access node, the second message.
In an example, the first message may comprise information of a packet data session (e.g., PDU session ID) associated with the data arrival. In an example, the first message may comprises at least one of an identifier of the UE, an identifier of a packet data session associated with the data arrival, an N1 SM container (e.g., SM message), N2 SM information (QFI(s), QoS profile(s), CN N3 Tunnel Info and/or S-NSSAI), Area of validity for N2 SM information, ARP, Paging Policy Indicator, 5QI, N1N2TransferFailure Notification Target Address and/or Extended Buffering support.
In an example, based on the information of the packet data session of the first message, the first network node may determine the network service (e.g., network slice) associated with the data arrival. In an example, based on the determined network service, the first network node may include in the second message, the information of the determined network service.
In an example, during interface setup procedure (e.g., NG setup), the one or more access nodes may send to the first network node, information of the supported network service. The information of the supported network service may comprise information of a network service supported by the one or more access nodes. Different access nodes may support different network service and may send different information of the supported network service. Based on the information from the one or more access nodes, the first network node may determine whether an access node supports the network service associated with the arrived data.
In an example, the network service may be a network slice.
In an example, if the selected access node receives the second message, the selected access node may send one or more message (e.g., paging messages) indicating the data arrival. In an example, the access node may send the one or more message indicating the data arrival via one or more cells which support the network service/slice associated with the data arrival. In an example, the access node may not send the one or more message indicating the data arrival via one or more cells which do not support the network service/slice associated with the data arrival. While the UE is in RRC idle state, the UE may monitor a paging channel. Via the paging channel, the UE may receive a message of the one or more paging messages (e.g., paging message) sent by the selected access node.
In an example, the second message may comprise at least one of an identifier of the UE (e.g., UE paging identity, S-TMSI, etc.), one or more tracking area identifiers (TAIs), information of a paging priority, a radio capability of the UE for paging, information of paging discontinuous reception (DRX), information of coverage restriction, a wake-up signal (WUS) assistance information, an information of a network service/slice associated with the data arrival or a group identifier of a network slice group comprising the network slice associated with the data arrival.
In an example, the UE may be registered to the first network node. When the UE is registered to the first network node, the first network node determines a registration area for the UE. The registration area may comprise a first access nodes and a second access nodes. The first access nodes may comprise one or more first cells. The second access node may comprise one or more second cells. The first access node may support the network service associated with the data arrival. The second access node may not support the network service associated with the data arrival. When the first network node selects the access node to which the first network node sends the second message, the first network node may select the first access node from the one or more access nodes of the registration area. The first network node may send the second message to the selected first access node. The first network node may not send the second message to the second access node.
In an example, the first network node (e.g., AMF) may manage access and mobility status of the UE. For example, the first network node may determine whether to grant an access from the UE to the network. For example, the first network node may determine a registration status of the UE. In an example, the second network node (e.g., SMF) may manage status of a packet data session of the UE. In an example, the access node comprises at least one of gNB and ng-eNB and non-3GPP interworking function (N3IWF).
In an example, if the second access node from the one or more access nodes does not support the network service associated with the data arrival, the first network node may not send to the second access node, a message (e.g., N2 paging message) indicating the data arrival for the UE.
In an example, if the UE fails to receive the paging message, for example, due to out of coverage, the UE may not send a service request to the first network node within a first time period. If the first network node does not receive the service request from the UE, within the first time period after sending the second message, the first network node may send to the second access node, a third message (e.g., N2 paging message) indicating the data arrival for the UE.
In an example, if the UE receives the paging message via the cell, the UE may send to the first network node, a service request. If the first network node receives the service request from the UE, the first network node may send to the second network node, a configuration request (e.g., session update, session management context request) for the packet data session associated with the data arrival. Based on the configuration request, the second network node may configure network resources for the UE. The second network node may send to the first network node, a configuration response (e.g., session update, session management context response) comprising configuration parameters of the packet data session.
In an example, a first node (e.g., an AMF, gNB-CU) may receive a message indicating a data activity for a UE. The message indicating the data activity for the UE may comprise a network service information (e.g., an information of a network slice). For the received message indicating the data arrival for the UE, the first node may determine whether a second node (e.g., NG-RAN, gNB-DU) supports a network service indicated by the network service information. If the second node supports the network service indicated by the network service information, the first node sends to the second node, a second message indicating the data activity for the UE. The second message may comprise the network service information. If the second node does not support the network service indicated by the network service information, the first node does not send to the second node, a second message indicating the data activity for the UE.
In an example, a first node (e.g., gNB-CU) may receive a message indicating a data activity for a UE. The message indicating the data activity for the UE may comprise a network service information (e.g., an information of a network slice). For the received message indicating the data arrival for the UE, the first node may determine whether a cell of the first node supports a network service indicated by the network service information. If the cell supports the network service indicated by the network service information, the first node sends a second message (e.g., paging message) indicating the data activity via the cell. The second message may comprise the network service information. If the cell node does not support the network service indicated by the network service information, the first node does not send the second message via the cell.
In an example, a UE may send to a network node, a registration request. The registration request may comprise one or more network services (e.g., network slices). The UE may receive from an access node, a message (e.g., paging message) indicating a data arrival for the UE. The message indicating the data arrival for the UE may comprise a network service information (e.g., network slices or group of network slices) associated with the data arrival. The UE may determine whether to respond to the message, based on the network service information. For example, if the network service indicated by the network service information is supported, the UE may determine to respond. For example, the UE may determine based on the location of the UE and/or supported network service by the access node. If the UE determines to respond, the UE may send a message (e.g., service request) to respond to the message indicating the data arrival.
In an example, an access node (e.g., NG-RAN) may receive from a network node (e.g., AMF), a message (e.g., N2 paging message) indicating data arrival for a UE. The message may comprise at least one of an identity of the UE, a network service information associated with the arrived data. The network service information may comprise an information on a network slice associated with the arrived data. When the access node receives the message (e.g., N2 paging message), the access node may send to the UE via a cell, a paging message indicating the data arrival. The paging message may comprise the network service information associated with the data arrival.
This application is a continuation of International Application No. PCT/US2022/048942, filed Nov. 4, 2022, which claims the benefit of U.S. Provisional Application No. 63/275,816, filed Nov. 4, 2021, all of which are hereby incorporated by reference in their entireties.
| Number | Date | Country | |
|---|---|---|---|
| 63275816 | Nov 2021 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/US2022/048942 | Nov 2022 | WO |
| Child | 18654224 | US |
