multiple access data connection on a mobile network

专利摘要:
Apparatus, methods and systems are disclosed to establish data paths through the multiple access network for a multiple access data connection. An apparatus 400 includes a processor 405 and a transceiver 425 that communicates with one or more network functions on a mobile communication network. The 405 processor receives a first session management request via an AMF. Here, the first session management request contains a second session management request sent by a remote unit that communicates with the mobile communication network through a first access network and a second access network, the second management request session being sent by the second access network. Processor 405 sends a first request to the access management function to establish a first data path for a multiple access data connection through the first access network and sends a second request to the access management function to establish a second path data for multiple access data connection through the second access network. Here, the first data path and the second data path are anchored in a common user plan network function in the mobile communication network.
公开号:BR112020000662A2
申请号:R112020000662-9
申请日:2017-07-10
公开日:2020-07-14
发明作者:Apostolis Salkintzis；Dimitrios Karampatsis
申请人:Motorola Mobility Llc；
IPC主号:

专利说明:

[0001] [0001] The material disclosed here generally refers to wireless communications and, more particularly, to the establishment of data paths through a multiple access network for a multiple access data connection. BACKGROUND
[0002] [0002] The following abbreviations and acronyms are defined here, at least some of which are mentioned in the description below.
[0003] [0003] 3rd generation partnership project ("3GPP"), positive recognition ("ACK"), access and mobility management function ("AME"), binary phase shift modulation ("BPSK"), aggregation of carrier ("CA"), free channel evaluation ("CCA"), control channel element ("CCE"), channel status information ("CSI"), Common search space ("CSS"), dispersion discrete Fourier transform ("DFT-S"), downlink control information ("DCI"), discrete Fourier transform dispersion OFDM ("DFT-S-OFDM"), downlink ("DL"), downlink pilot time interval ("DwWwPTS"), enhanced free channel assessment ("eCCA"), enhanced mobile broadband ("eMBB"), evolved NodeB ("eNB"), European Telecommunications Standards Institute (" ETSI "), frame-based equipment (" FBE "), frequency division duplex (" FDD "), frequency division multiple access (" FDMA "), guard period (" GP "), automatic repeat request hybrid ("HARQ"), Internet of Things ("IoT"), key performance indicators ("KPI"), licensed assisted access ("LAA"), charge-based equipment ("LBE"), listening before speaking ("LBT"), long-term evolution ("LTE"), advanced LTA ("LTE-A"), media access control ("MAC"), multiple access ("MA"), modulation coding scheme ("MCS"), machine type communication ("MTC"), massive MTC ("mMMTC"), multiple inputs and multiple outputs ("MIMO"), multipath TCP ("MPTCP"), shared access by multiple users ("MUSA"), narrow band ("NB"), negative recognition ("NACK") or ("NAK"), network function ("NF"), next-generation NodeB ("gNB"), multiple access non-orthogonal ("NOMA"), orthogonal frequency division multiplexing ("OFDM"), primary cell ("PCell"), physical transmission channel ("PBCH"), physical downlink control channel ("PDCCH" ), physical downlink shared channel ("PDSCH"), multiple access by standard division ions ("PDMA"), physical hybrid indicator channel ARQ ("PHICH"), physical random access channel ("PRACH"), physical resource block ("PRB"), physical uplink control channel ("PUCCH" ), shared physical uplink channel ("PUSCH"), quality of service ("QoS"), quadrature phase shift modulation ("QPSK"), radio resource control ("RRC"), access procedure random ("RACH"), random access response ("RAR"), reference signal ("RS"), multiple resource propagation access ("RSMA"), round trip time ("RTT"), reception ("RX"), sparse code multiple access ("SCMA"), switch / split function ("SSE"), scheduling request ("SR"), session management function ("SME"), audible reference ("SRS"), single carrier frequency division multiple access ("SC-FDMA"), secondary cell ("SCell"), shared channel ("SCH"), signal-interference-more-noise ratio ( "SINR"), system information block ("SIB"), transport block ("TB"), transport block size ("TBS"), transmission control protocol ("TCP"), time division duplexing ("TDD"), multiplexing by time division ("TDM") transmission and reception point ("TRP"), transmission ("TX"), uplink control information ("UCI"), user datagram protocol ("UDP") entity / user equipment (mobile terminal) ("UE"), uplink ("UL"), universal mobile telecommunications system ("UMTS"), uplink pilot time interval ("UpPTS"), ultra-reliable communications and low latency ("URLLC") and worldwide interoperability for microwave access ("WiMAX"). As used in this document, "HARQ-ACK" can collectively represent positive recognition ("ACK") and negative recognition ("NAK"). ACK means that a TB is received correctly, while NAK means that a TB is received incorrectly.
[0004] [0004] In 5G networks, the main network is to support multiple access PDU sessions (MA-PDU) between 3GPP access networks (including LTE, evolved LTE and Novo Rádio) and non-3GPP access networks (usually WLAN). A MA-PDU session refers to a data session composed of two (and, rarely, more) PDU sessions that share the same attributes (for example, the same S-NSSAI, the same SSC mode the same DNN, the same type, same address / prefix etc.),
[0005] [0005] However, the establishment of a MA-PDU session currently requires two separate PDU sessions requested by the UE. First, an initial PDU session over an access is established and then an additional PDU session over a different access is also established. The additional PDU session becomes "linked" to the initial PDU session because it was established on the same APN and also because it contains an indication of Network Based IP Flow Mobility ("NBIFOM"). BRIEF SUMMARY
[0006] [0006] Methods for establishing a multiple access data connection are disclosed. Apparatus and systems also perform the functions of the methods. In some embodiments, a method of a session management function for establishing a multiple access data connection includes receiving a first session management request via an access management function on a mobile network. Here, the first session management request contains a second session management request sent by a remote unit communicating with the mobile communication network through a first access network and a second access network. The method includes sending a first request to the access management function to establish a first data path for the multiple access data connection over the first access network, in response to the first session management request. The method includes sending a second request to the access management function to establish a second data path for the multiple access data connection over the second access network, where the first data path and the second data path are anchored in a common user plan network role on the mobile network, in response to the first session management request. In one embodiment, the second session management request is sent through the second access network.
[0007] [0007] In certain embodiments, a method of a UE to establish a multiple access data connection includes communicating with a mobile communication network through a first access network and a second access network and transmitting a request, through second access network, to establish a data connection. The method includes receiving a first request to configure a first data carrier for the data connection on the first access network in response to the request and receiving a second request to configure a second data carrier for the data connection on the second access network in response to the request, where the first data bearer and the second data bearer are used to carry traffic from the data connection. BRIEF DESCRIPTION OF THE DRAWINGS
[0008] [0008] A more particular description of the modalities briefly described above will be rendered by reference to specific modalities that are illustrated in the attached drawings. Understanding that these drawings represent only some modalities and, therefore, should not be considered limiting the scope, the modalities will be described and explained with specificity and additional details through the use of the attached drawings, in which:
[0009] [0009] As will be appreciated by a technician in the subject, aspects of the modalities can be incorporated as a system, apparatus, method or program product. Therefore, modalities can take the form of an entirely hardware modality, an entirely software modality (including firmware, resident software, microcode, etc.) or a modality that combines aspects of software and hardware.
[0010] [0010] For example, the described modalities can be implemented as a hardware circuit comprising custom large-scale integration circuits ("VLSI") or arrays of ready-to-use semiconductors, such as logic chips, transistors or other discrete components . The disclosed modalities can also be implemented in programmable hardware devices, such as field programmable door arrays, programmable matrix logic, programmable logic devices or the like. As another example, the disclosed modalities may include one or more physical or logical blocks of executable code that can, for example, be organized as an object, procedure or function.
[0011] [0011] In addition, the modalities may take the form of a program product embedded in one or more computer-readable storage devices that store machine-readable code, computer-readable code and / or program code, referred to below as code . Storage devices can be tangible, non-transitory and / or non-transmitting. Storage devices may not incorporate signals. In a certain embodiment, storage devices employ only signals to access the code.
[0012] [0012] Any combination of one or more computer-readable media can be used. The computer-readable medium can be a computer-readable storage medium. The computer-readable storage medium may be a storage device that stores the code. The storage device may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, holographic, micromechanical or semiconductor system, device or device, or any suitable combination of the foregoing.
[0013] [0013] More specific examples (a non-exhaustive list) of the storage device include the following: an electrical connection with one or more wires, a portable floppy disk, a hard disk, a random access memory ("RAM"), a read-only memory ("ROM"), a programmable erasable read-only memory ("EPROM" or Flash memory), a portable read-only memory for a portable compact disc ("CD-ROM"), an optical storage device, a device magnetic storage device or any suitable combination of the previous items. In the context of this document, a computer-readable storage medium may be any tangible medium that may contain or store a program for use by or in connection with a system, apparatus or device for carrying out instructions.
[0014] [0014] The reference throughout this Descriptive Report to "a modality", "a modality" or similar language means that a specific feature, structure or characteristic described in connection with the modality is included in at least one modality. Thus, the appearances of the phrases "the modality", "in a modality" and a similar language throughout this Descriptive Report may, but not necessarily, all refer to the same modality, but mean "one or more, but not all modalities "unless expressly specified otherwise. The terms "including", "comprising", "having" and variations thereof mean "including, but not limited to", unless expressly specified otherwise. An enumerated list of items does not imply that any or all of the items are mutually exclusive, unless expressly specified otherwise. The terms "one", "one" and "o" also refer to "one or more", unless expressly specified otherwise.
[0015] [0015] In addition, the characteristics, structures or characteristics described of the modalities can be combined in any appropriate way. In the following description, numerous specific details are provided, such as scheduling examples, software modules, user selections, network transactions, database queries, database structures, hardware modules, hardware circuits, chips hardware, etc., to provide a complete understanding of modalities. A person skilled in the art will recognize, however, that modalities can be practiced without one or more of the specific details, or with other methods, components, materials and so on. In other cases, known structures, materials or operations are not shown or described in detail to avoid obscuring aspects of a modality.
[0016] [0016] Aspects of the modalities are described below with reference to schematic flowchart diagrams and / or schematic block diagrams of methods, apparatus, systems and program products according to the modalities. It will be understood that each block of the schematic flowchart diagrams and / or schematic block diagrams and combinations of blocks in the schematic flowchart diagrams and / or schematic block diagrams, can be implemented by code. This code can be provided to a general-purpose computer processor, special-purpose computer, or other programmable data-processing device to produce a machine, so that instructions executed by the computer's processor or other programmable data-processing device create means to implement the functions / acts specified in the flowchart schematic diagrams and / or block schematic diagrams.
[0017] [0017] The code can also be stored on a storage device that can direct a computer, another programmable data processing device or other devices to function in a specific way, so that the instructions stored on the storage device produce an article manufacturing instructions, including instructions that implement the function / act specified in the schematic flowchart diagrams and / or schematic diagram blocks.
[0018] [0018] The code can also be loaded on a computer, another programmable data processing device or other devices to cause a series of operational steps to be performed on the computer, another programmable device or other devices to produce a computer-implemented process , so that the code that runs on the computer or other programmable device provides processes to implement the functions / acts specified in the schematic flowchart diagrams and / or schematic diagram blocks.
[0019] [0019] The schematic flowchart diagrams and / or schematic block diagrams in the Figures illustrate the architecture, functionality and operation of possible implementations of apparatus, systems, methods and program products according to various modalities. In this regard, each block in the flowchart schematics and / or block schematics can represent a module, segment or part of the code, which includes one or more executable instructions from the code to implement the specified logic functions.
[0020] [0020] It should also be noted that, in some alternative implementations, the functions observed in the block may occur outside the order indicated in the Figures. For example, two blocks shown in succession can, in fact, be executed substantially simultaneously, or the blocks can sometimes be executed in reverse order, depending on the functionality involved. Other steps and methods that are equivalent in function, logic or effect to one or more blocks, or parts thereof, of the illustrated Figures can be designed.
[0021] [0021] The description of the elements in each figure can refer to elements in the following figures. Similar numbers refer to similar elements in all figures, including alternative modalities of similar elements.
[0022] [0022] Methods, apparatus and systems are disclosed to allow an UE to establish a multiple access PDU (MA-PDU) session or other multiple access data connection by sending a single session management request (SM) message to the mobile communication network. As described herein, the establishment of a multiple access data connection can be initiated by the UE or initiated by the network. Although an MA-PDU session is commonly used as an example to describe the establishment of the multiple access data connection, other types of multiple access data connection can be established using the disclosed methods, apparatus, systems and procedures.
[0023] [0023] Figure 1 represents a wireless communication system 100 for establishing a multiple access data connection, according to disclosure modalities. In one embodiment, the wireless communication system 100 includes at least one remote unit 105, a 3GPP access network 120 containing at least one cellular base unit 125, a non-3GPP access network 130, 3GPP communication links 123, communication links non-3GPP access communication 133 and a mobile primary network 140. Although a specific number of remote units 105, 3GPP access networks 120, base units 125, 3GPP communication links 123, non-3GPP access networks 130, non-3GPP communication links 133 and main mobile networks 140 are represented in Figure 1, one skilled in the art will recognize that any number of remote units 105, 3GPP access networks 120, base units 125, 3GPP communication links 123, non-3GPP access networks 130, non-3GPP communication 133 and main mobile networks 140 can be included in the wireless communication system 100.
[0024] [0024] In an implementation, the wireless communication system 100 is compatible with the 5G system specified in the 3GPP specifications. More generally, however, wireless communication system 100 can implement some other open or proprietary communication network, for example, LTE or WiMAX, among other networks. This disclosure is not intended to be limited to the implementation of any specific wireless communication system or architecture.
[0025] [0025] In one embodiment, remote units 105 may include computing devices such as desktop computers, laptops, personal digital assistants ("PDAS"), tablet computers, smartphones, smart televisions (for example, televisions connected to the Internet), smart devices (for example, devices connected to the Internet), decoders, game consoles, security systems (including security cameras), computers on board vehicles, network devices (for example, routers, switches, modems) or similar. In some embodiments, remote units 105 include wearable devices, such as smart watches, fitness bracelets, head-mounted optical screens or the like. In addition, remote units 105 can be referred to as subscriber units, cell phones, mobile stations, users, terminals, mobile terminals, fixed terminals, subscriber stations, UE, user terminals, a device or by other terminology used in the state of technical. Remote units 105 can communicate directly with one or more of the base units 125 via uplink ("UL") and downlink ("DL") communication signals. In addition, UL and DL communication signals can be transported via 3GPP 123 communication links. Likewise, remote units 105 can communicate with one or more non-3GPP 130 access networks via UL and DL communication signals. transported through non-3GPP 133 communication links.
[0026] [0026] In some embodiments, remote units 105 communicate with a remote host 155 over a network connection to the main mobile network 140. For example, a remote unit 105 can establish a PDU connection (or other data connection) with the mobile main network 140 using a 3GPP access network 120 and / or a non-3GPP access network 130. Mobile main network 140 relays traffic between remote unit 105 and remote host 155 using the PDU connection. In other embodiments, remote unit 105 can communicate with remote host 155 via non-3GPP access network 130 without traffic passing through mobile main network 140. This is called direct offload.
[0027] [0027] Base units 125 can be distributed across a geographic region. In certain embodiments, a base unit 125 can also be referred to as an access terminal, a base, a base station, a NodeB, an eNB, a gNB, a Domestic NodeB, a relay node, a device, or by any other terminology used in the prior art. Base units 125 are generally part of a radio access network ("RAN"), such as the 3GPP access network 120, which may include one or more controllers coupled communicably to one or more corresponding base units 125. These and other elements of the radio access network are not illustrated, but are generally well known to those skilled in the art. The base units 125 connect to the main mobile network 140 via the 3GPP access network 120.
[0028] [0028] Base units 125 may serve a number of remote units 105 within a service area, for example, a cell or a cellular sector via a wireless communication link. Base units 125 can communicate directly with one or more of remote units 105 via communication signals. Generally, base units 125 transmit downlink ("DL") communication signals to serve remote units 105 in the time, frequency and / or spatial domain. In addition, DL communication signals can be transported via 3GPP 123 communication links. 3GPP 123 communication links can be any suitable carrier in the licensed or unlicensed radio spectrum. The 3GPP 123 communication links facilitate communication between one or more of the remote units 105 and / or one or more of the base units 125.
[0029] [0029] Non-3GPP 130 access networks can be distributed across a geographic region. Each non-3GPP access network 130 can serve a number of remote units 105 with a service area. Typically, a service area of the non-3GPP access network 130 is smaller than the service area of a base unit 125. Non-3GPP access networks 130 can communicate directly with one or more remote units 105, receiving UL communication signals. and transmitting DL communication signals to serve remote units 105 in the time, frequency and / or spatial domain. DL and UL communication signals are carried by non-3GPP 133 communication links. 3GPP 123 communication links and non-3GPP 133 communication links can employ different frequencies and / or different communication protocols. A non-3GPP 130 access network can communicate using unlicensed radio spectrum. Mobile master network 140 can provide services to a remote unit 105 via non-3GPP access networks 130, as described in more detail here.
[0030] [0030] In some modalities, a non-3GPP access network 130 connects to the main mobile network 140 through a non-3GPP interworking function ("N3IWE") 135. The N3IWF 135 provides interworking between a non-3GPP AN 120 and the mobile main network 140, supporting connectivity through the "N2" and "N3" interfaces. As shown, the access network 3GPP 120 and the N3IWF 135 communicate with the AMF 145 using an "N2" interface and with the UPFs 141, 142 using an "N3" interface.
[0031] [0031] In certain modalities, a non-3GPP access network 130 can be controlled by an operator of the main mobile network 140 and can have direct access to the main mobile network 140. This non-3GPP AN deployment is called "non-3GPP access network trustworthy". A non-3GPP 130 access network is considered "trusted" when it is operated by the 3GPP carrier or a trusted partner and supports certain security features, such as strong overhead encryption. While the N3IWF 135 is described as being located outside the non-3GPP 130 access network and the main network 140, in other embodiments the N3IWF 135 can be colocalized with the non-3GPP 130 access network (for example, if the 3GPP access network 130 is a trusted non-3GPP access network) or located within the primary network
[0032] [0032] In one embodiment, the main mobile network 140 is a 5G core ("5GC") or the evolved packet core ("EPC"), which can be coupled to another 150 data network, such as the Internet and networks of private data, among other data networks. Each major mobile network 140 belongs to a single public terrestrial mobile network ("PLMN"). This disclosure is not intended to be limited to the implementation of any specific wireless communication system or architecture.
[0033] [0033] The main mobile network 140 includes several network functions ("NFs"). As represented, the main mobile network
[0034] [0034] As shown, a remote unit 105 can be connected to a base unit 125 on a 3GPP access network 120 and to a base unit (not shown in Fig. 1) on a non-3GPP access network 130. The remote unit 105 can transmit a request to establish a data connection via a 3GPP access network 120 and non-3GPP access network 130. In some embodiments, the request includes an indication that a multiple access data connection must be established (for example, example, a multiple access data connection initiated by UE). For example, remote unit 105 may indicate that a multiple access data connection must be established including a first session identifier (for example, associated with the 3GPP 120 access network) and a second session identifier (for example, associated with the access network device does not
[0035] [0035] After receiving the request to establish a data connection, SMF 146 initiates the multiple access data connection by triggering the establishment of a data path (for example, a child PDU session) through the non-3GPP access network 130 and triggering the establishment of another data path (for example, another child PDU session) over the 3GPP 120 access network. For example, SMF 146 can trigger the establishment of a data path by sending a session management request ("SM ") for AMF 145, as described below with reference to Figures 5-7. Note that the multiple access data connection is anchored to a common UPF (for example, UPEF-A 143).
[0036] [0036] Figure 2 represents a network architecture 200 used to establish a multiple access data connection, according to disclosure modalities. Network architecture 200 can be a simplified embodiment of wireless communication system 100. As shown, network architecture 200 includes a UE 205 that communicates with mobile communication network 210 through a RAN 5G 215 and a WLAN 220 , such as a Wi-Fi RAN. The 5G RAN 215 is a modality of the 3GPP 120 access network and WLAN 220 is a modality of the non-3GPP 130 access network, described above. The mobile communication network 210 is a modality of the main network 140, described above, and includes a first UPF 141, a second UPF 142, an UPF anchor 143, an AMF 145 and an SMF 146. WLAN 220 accesses the communication network mobile via N3IWF 135, which can be colocalized with WLAN 220, located on the main mobile network, or located outside WLAN 220 and the main mobile network, as described above. The N3IWF 135 communicates with the AMF 145 through an "N2" interface and with the second UPF 142 through the "N3" interface. The 5G RAN 215 communicates with the AMF 145 through an "N2" interface and with the first UPF 141 through an "N3" interface.
[0037] [0037] As depicted, the UE 205 includes a protocol stack containing an IP 201 layer, a virtual interface layer 203, a WLAN 207 interface and a 5G 209 radio interface. After sending the single request to establish a network connection, data (for example, a MA-PDU session), as described here, the UE 205 receives a request to configure a first data carrier for the data connection (corresponding to the first daughter PDU session 225) on the 5G RAN 215 and a request to configure a second data carrier for the data connection (corresponding to the second daughter PDU session 230) on WLAN 220. Requests include one or more session identifiers included in the unique request to let the UE 205 know that both are for the same session MA-PDU.
[0038] [0038] Therefore, the UE 205 establishes a multiple access data connection (represented here as a MA-PDU session) that has two daughter PDU sessions: a first daughter PDU session 225 that uses the 5G 209 radio interface and the 5G RAN 215 and a second daughter PDU session 230 that uses the WLAN 207 interface and WLAN 220 (for example, a public Wi-Fi access point). The two daughter PDU sessions are connected in the UE at the "virtual interface" layer 203, which exposes a single IP interface to the upper layers (for example, the IP layer 201). As a result, the two daughter PDU sessions share the same IP address and make up a multi-link data connection between the UE 205 and the UPF-A 143. Figure 2 shows a scenario with three UPFs: the first UPF 141 in interface with the 5G RAN 215, the second UPF 142 in interface with the N3IWF 135 and the UPF anchor
[0039] [0039] Figure 3 represents a modality of a UE 300 device that can be used to establish a multiple access data connection, according to the disclosure modalities. The UE device 300 may be a form of the remote unit 105. Furthermore, the UE device 300 may include a processor 305, a memory 310, an input device 315, a screen 320, a first transceiver 325 and a second transceiver 330.
[0040] [0040] The first transceiver 325 communicates with a mobile communication network (for example, the main mobile network 140) through a first access network, while the second transceiver 330 communicates with the mobile communication network through a second access network. The first and second access networks facilitate communication between the main mobile network 140 and the UE 300 device. In one embodiment, the first access network is the 5G RAN 215 or another 3GPP 120 access network and the second access network is WLAN 220 or another non-3GPP access network
[0041] [0041] Processor 305, in one embodiment, can include any known controller capable of executing computer-readable instructions and / or capable of performing logical operations. For example, processor 305 can be a microcontroller, a microprocessor, a central processing unit ("CPU"), a graphics processing unit ("GPU"), an auxiliary processing unit, an array of field programmable ports ( "FPGA"), or similar programmable controller. In some embodiments, processor 305 executes instructions stored in memory 310 to execute the methods and routines described herein. Processor 305 is communicatively coupled to memory 310, input device 315, screen 320, first transceiver 325 and second transceiver 330.
[0042] [0042] En - some modalities, processor 305 transmits a request to establish a data connection. In certain embodiments, the request to establish a data connection comprises an indication to establish the data connection through the first and second access networks. In one embodiment, the indication for establishing the data connection through the first and second access networks comprises a first session identifier associated with the first access network and a second session identifier associated with the second access network. In another embodiment, the indication for establishing the data connection through the first and second access networks comprises a first session identifier and a multiple access parameter. Here, the first session identifier is associated with the first access network and the second access network.
[0043] [0043] In some embodiments, processor 305 transmits the request to establish a data connection through the second access network. In addition, the request to establish a data connection contains a session identifier associated with the second access network and does not contain a session identifier associated with the first access network. In certain embodiments, the request to establish a data connection comprises a mode parameter, the mode parameter containing a requested operating mode for a multiple access data connection.
[0044] [0044] In certain modalities, the first access network is an access network not defined by 3GPP ("non-3GPP access") and the second access network is an access network defined by 3GPP ("3GPP access"). In such modalities, the request to establish a data connection can be a session request from the Packet Data Unit ("PDU").
[0045] [0045] Processor 305 receives a first request to configure a first data carrier for data connection through the first access network in response to the request also receives a second request to configure a second data carrier for data connection over the second access network in response to the request. Here, the first data carrier and the second data carrier are used to carry traffic from the data connection.
[0046] [0046] In certain modalities, the request to establish a data connection contains a session identifier associated with the second access network and does not contain an indication to establish the data connection through the first and second access networks. In addition, the first request to configure a first data bearer for the data connection on the first access network and the second request to configure a second data bearer for the data connection on the second access network include the associated session identifier. to the second access network. In such embodiments, processor 305 determines that the request through the second access network to establish a data connection has initiated the establishment of a multiple access data connection through the first access network and the second access network.
[0047] [0047] Memory 310, in one mode, is a computer-readable storage medium. In some embodiments, memory 310 includes a volatile computer storage medium. For example, memory 310 may include RAM, including dynamic RAM ("DRAM"), synchronous dynamic RAM ("SDRAM") and / or static RAM ("SRAM"). In some embodiments, memory 310 includes non-volatile computer storage media. For example, memory 310 may include a hard disk drive, flash memory or any other suitable non-volatile computer storage device. In some embodiments, memory 310 includes volatile and non-volatile computer storage media. In some embodiments, memory 310 stores data related to the establishment of a multiple access data connection, for example, storing session identifiers, protocol stacks, security keys, messages and the like. In some embodiments, memory 310 also stores program code and related data, such as an operating system or other controller algorithms operating on the UE 300 device and one or more software applications.
[0048] [0048] Input device 315, in one embodiment, may include any known computer input device, including a touch panel, button, keyboard, pen, microphone or the like. In some embodiments, the input device 315 can be integrated with the screen 320, for example, as a touch screen or similar touch screen. In some embodiments, the input device 315 includes a touchscreen, so that text can be entered using a virtual keyboard displayed on the touchscreen and / or handwritten on the touchscreen. In some embodiments, the input device 315 includes two or more different devices, such as a keyboard and a touchscreen.
[0049] [0049] Monitor 320, in one mode, can include any electronically controlled screen or screen device known. Screen 320 can be designed to emit visual, audible and / or haptic signals. In some embodiments, screen 320 includes an electronic screen capable of emitting visual data to a user. For example, screen 320 may include, but is not limited to, an LCD screen, an LED screen, an OLED screen, a projector or similar screen device capable of outputting images, text or the like to a user. As another non-limiting example, screen 320 may include a wearable screen, such as a smart watch, smart glasses, an alert screen or the like. In addition, screen 320 may be a component of a smart phone, personal digital assistant, television, desktop computer, notebook (laptop), personal computer, vehicle dashboard or the like.
[0050] [0050] In certain modalities, the screen 320 includes one or more speakers to produce sound. For example, screen 320 may produce an alert or beep notification (for example, a beep or beep). In some embodiments, the screen 320 includes one or more haptic devices to produce vibrations, movement or other haptic feedback. In some embodiments, all or part of the screen 320 can be integrated with the input device 315. For example, the input device 315 and the screen 320 can form a touch screen or similar touch screen. In other embodiments, the screen 320 may be located close to the input device 315. In certain embodiments, the UE device 300 may not include any input device 315 and / or screen 320.
[0051] [0051] As discussed above, the first transceiver 325 communicates with a mobile communication network through a first access network, while the second transceiver 330 communicates with the mobile communication network through a second access network. Transceivers 325 and 330 operate under the control of processor 305 to transmit messages, data and other signals and also to receive messages, data and other signals. For example, processor 305 can selectively activate one or both of the transceivers 325, 330 (or parts thereof) at specific times in order to send and receive messages. The first transceiver 325 may include one or more transmitters and one or more receivers for communication through the first access network. Likewise, the second transceiver 330 may include one or more transmitters and one or more receivers for communication through the second access network. As discussed above, the first transceiver 325 and the second transceiver 330 can support one or more network interfaces for communicating with the mobile communication network.
[0052] [0052] Figure 4 represents a modality of a 400 session management device that can be used to establish a multiple access data connection, according to the disclosure modalities. The session management device 400 can be a modality of SMF
[0053] [0053] As shown, transceiver 425 includes at least one transmitter 430 and at least one receiver 435. In addition, transceiver 425 can support at least one network interface 440, such as an "Na" interface used for communications between a UE and the session management device 400. Here, the network interface 440 facilitates communication with a network function such as the AMF 145, PCF 148 and / or UDM 149. In addition, at least one 440 network interface can include an "N11" interface used for communications with an AMF, an "N4" interface used for communication with a UDM and the like.
[0054] [0054] The 405 processor, in one embodiment, can include any known controller capable of executing computer-readable instructions and / or capable of executing logical operations. For example, processor 405 can be a microcontroller, a microprocessor, a central processing unit ("CPU"), a graphics processing unit ("GPU"), an auxiliary processing unit, an array of field programmable ports ( "FPGA"), or similar programmable controller. In some embodiments, processor 405 executes instructions stored in memory 410 to execute the methods and routines described herein. Processor 405 is communicatively coupled to memory 410, input device 415, screen 420 and transceiver 425.
[0055] [0055] In some embodiments, the 405 processor receives a first session management request ("SM") through an access management function. Here, the first SM request contains a second SM request sent by a remote unit (for example, the second SM request is incorporated in the first SM request). The remote unit communicates with the mobile communication network through a first access network and a second access network and has simultaneous connections on both access networks. In one embodiment, the remote unit sends the second SM message through the first access network. In another embodiment, the remote unit sends the second SM message through the second access network. In one embodiment, the second SM message includes a mode parameter, the mode parameter that contains a requested operating mode for a multiple access data connection.
[0056] [0056] In response to the first session management request, processor 405 sends a first request to the access management function to establish a first data path for a multiple access data connection through the first access network. In some embodiments, processor 405 determines to form the multiple access data connection based on the content of the first SM request. For example, the first SM request can include a multiple access parameter or a specific request for a multiple access data connection. As another example, processor 405 can determine to form the multiple access data connection in response to a need to offload data traffic to a non-3GPP access network.
[0057] [0057] Processor 405 also sends a second request to the access management function to establish a second data path for the multiple access data connection through the second access network, in response to the first session management request, wherein the first data path and the second data path are anchored in a common user plan network function in the mobile communication network. In some embodiments, the establishment of the first and second data paths can occur simultaneously.
[0058] [0058] Where the establishment is sequential, the first data path established (in time) is determined based on the access network used by the remote unit to send the second SM request. For example, where the second SM message is sent over the first access network, the second data path through the second access network will be established before the first data path. As another example, where the second SM message is sent over the second access network, the first data path through the first access network will be established before the second data path.
[0059] [0059] In some embodiments, the first session management request (for example, received from the AMF) contains an indication to establish a multiple access data connection to the remote unit through a first access network and a second access network. access. For example, the indication to establish a multiple access data connection to the remote unit on a first access network and a second access network can be a first session identifier associated with the first access network and a second associated session identifier. to the second access network. As another example, the indication to establish a multiple access data connection to the remote unit via a first access network and a second access network can be a multiple access parameter included with a (unique) session identifier.
[0060] [0060] In certain embodiments, processor 405 queries a policy control function for at least one of the multiple access routing rules and multiple access QoS rules associated with the remote unit. Here, multiple access QoS rules include QoS rules for the first access network and QoS rules for the second access network. The multiple access routing rules tell you how to route multiple access data connection traffic through the first access network and the second access network. In addition, processor 405 can send a session establishment request to the common user plan function by anchoring the first and second data paths, the session establishment request including multiple access routing rules and an indication that the first and second data paths are for a multiple access data connection.
[0061] [0061] In some embodiments, the second session management request is a request from the remote unit to establish a data connection through a single access network. In addition, the management request for the first session may include an indication that the remote unit has simultaneous connections to the first access network and the second access network. In such embodiments, processor 405 can determine the establishment of a multiple access data connection in response to the receipt of the first session management request (and the indication that the remote unit has simultaneous connections to the first access network and the second access network).
[0062] [0062] In certain embodiments, the 405 processor also consults a data management function (for example, UDM 149) to determine whether a network subscription from the remote unit allows a multiple access connection in response to the receipt of the first request for session management. In such embodiments, processor 405 can determine the establishment of a multiple access data connection based on the remote unit's network signature. In certain embodiments, processor 405 also queries a policy control function (for example, PCF 148) for at least one of the multiple access routing rules and multiple access QoS rules associated with the requested data connection in response to the receipt of the first session management request and where the processor determines to establish the multiple access data connection based on at least one of the multiple access routing rules and multiple access QoS rules received from the policy control function.
[0063] [0063] In some modalities, the first access network is a non-3GPP access network (for example, an access network not defined by 3GPP) and the second access network is a 3GPP network (for example, an access network defined by 3GPP). In addition, the second SM request (for example, sent by the remote unit) can be a PDU session establishment request. In such an embodiment, sending the first request to the AMF to establish the first data path for the multiple access data connection may include the 405 processor sending a third SM request to the AMF without an embedded Nl Session Management container, the third SM request indicating that the AMF should send it to the first access network.
[0064] [0064] In addition, sending the second request to the AMF to establish the second data path for the multiple access data connection may include the 405 processor sending a response to the first SM request, where the response contains a container of Built-in Nl Session Management. Here, the embedded Nl Session Management container includes a response to the second SM message. Consequently, the embedded Nl Session Management container is sent over the same access network used by the remote unit to send the second SM message. In one embodiment, the Session Management container N1 includes an access message to the establishment of the PDU session that contains multiple access routing rules and multiple access quality of service ("QoS") rules associated with the access data connection multiple.
[0065] [0065] Memory 410, in one mode, is a computer-readable storage medium. In some embodiments, memory 410 includes a volatile computer storage medium. For example, memory 410 may include RAM, including dynamic RAM ("DRAM"), synchronous dynamic RAM ("SDRAM") and / or static RAM ("SRAM"). In some embodiments, memory 410 includes non-volatile computer storage media. For example, memory 410 may include a hard disk drive, flash memory or any other suitable non-volatile computer storage device. In some embodiments, memory 410 includes volatile and non-volatile computer storage media. In some - modalities, memory 410 stores data related to establishing a multiple access data connection, for example, storing session identifiers associated with a remote unit, protocol stacks, messages, security keys, access policy rules multiple and the like. In certain embodiments, memory 410 also stores program code and related data, such as an operating system or other controller algorithms operating on the session management apparatus 400 and one or more software applications.
[0066] [0066] Input device 415, in one embodiment, can include any known computer input device, including a touch panel, button, keyboard, pen, microphone or the like. In some embodiments, the input device 415 can be integrated with the screen 420, for example, as a touch screen or similar touch screen. In some embodiments, the input device 415 includes a touchscreen, so that text can be entered using a virtual keyboard displayed on the touchscreen and / or handwritten on the touchscreen. In some embodiments, the input device 415 includes two or more different devices, such as a keyboard and a touchscreen.
[0067] [0067] Screen 420, in one embodiment, can include any electronically controllable display screen or device known. The screen 420 can be designed to emit visual, audible and / or haptic signals. In some embodiments, the screen 420 includes an electronic screen capable of emitting visual data to a user. For example, screen 420 may include, but is not limited to, an LCD screen, an LED screen, an OLED screen, a projector or similar screen device capable of outputting images, text or the like to a user. As another non-limiting example, screen 420 may include a wearable screen, such as a smart watch, smart glasses, an alert screen or the like. In addition, the screen 420 can be a component of a smart phone, a personal digital assistant, a television, a desktop computer, a notebook (laptop), a personal computer, a vehicle panel or the like.
[0068] [0068] In certain modalities, the screen 420 includes one or more speakers for the production of sound. For example, screen 420 may produce an alert or beep notification (for example, a beep or beep). In some embodiments, the screen 420 includes one or more haptic devices to produce vibrations, movement or other haptic feedback. In some embodiments, all or parts of screen 420 can be integrated with the input device
[0069] [0069] Transceiver 425 communicates with one or more network functions of a mobile communication network. Transceiver 425 operates under the control of processor 405 to transmit messages, data and other signals and also to receive messages, data and other signals. For example, the 405 processor can selectively activate the transceiver (or parts of it) at specific times in order to send and receive messages. Transceiver 425 can include one or more transmitters 430 and one or more receivers 435. As discussed above, transceiver 425 can support one or more of network interface 440 for communication with base unit 125.
[0070] [0070] Figure 5 represents a network procedure 500 for establishing a multiple access data connection, according to disclosure modalities. The network procedure 500 is a procedure initiated by the UE to establish a multiple access data connection from a single request from the UE to establish a data connection. The network procedure involves the UE 205,
[0071] [0071] The network procedure 500 starts when the UE 205 wants to establish a MA-PDU session through both access networks and sends a NAS message to the AMF 145 that includes a "Request to establish a PDU session" (see operation 502 ). In the modalities of Figure 5A, the NAS message is sent via RAN 5G 215 (for example, the 3GPP access network), but in other modalities the NAS message can be sent via the non-3GPP access network. The NAS message also includes two PDU session identities: a first PDU session identity (ID-1l) associated with the 3GPP access network (for example, including the 5G RAN 215) and a second PDU session identity (ID-2) associated with the non-3GPP access network. This is in contrast to conventional NAS messages sent to the PDU session establishment, which always contain only one PDU session identity.
[0072] [0072] In certain modalities, the UE 205 indicates that it wishes to establish a MA-PDU over the 3GPP and non-3GPP access networks, including in the NAS message the two PDU session identities. The NAS message sent by the UE 205 can also include other information, such as the requested DNN (data network name), the type of slice requested, etc. In some embodiments, the message "Request to establish a PDU session" may include a mode parameter that indicates the requested operation mode of the MA-PDU session. For example, the mode parameter may indicate that the UE 205 prefers the MA-PDU session to operate in active / standby mode, with the child PDU session on a non-3GPP access network to be the "active" daughter and the session Daughter PDU on the 3GPP access network to be the "waiting" daughter. As another example, the UE 205 may prefer that the daughter PDU session on the 3GPP access network is the "active" daughter and the daughter PDU session on the non-3GPP access network is the "waiting" daughter.
[0073] [0073] In active / standby mode, all traffic from the MA-PDU session is transferred through the "active" daughter PDU session while the other daughter PDU session (the "waiting" daughter) does not carry any traffic. When the "active" daughter PDU session is unavailable on the UE 205 (for example, due to a lack of radio signal), it becomes a "waiting" daughter and the UE 205 transfers all traffic from the MA-PDU session to the other daughter PDU session that becomes the "active" daughter. When the network receives traffic from the UE 205 in a "waiting" child PDU session, it changes that child PDU session to "active". When the MA-PDU session operates in active / standby mode, it is not necessary to apply any multiple access routing rules (discussed below).
[0074] [0074] Next, AMF 145 selects an SMF 146 and sends an SM request (for example, a first SM request) to SMF 146 (see operation 504). The SM request includes the "PDU Session Establishment Request" received from the UE 205. The SM request also includes an Access Network Type parameter. Here, this parameter has the value "Type of access network = 3GPP" to indicate to SMF 146 that the request to establish a PDU session was received by the access network 3GPP (for example, the 5G RAN 215). Where the PDU Session Establishment Request is received by the non-3GPP access network, then a value "Type of access network = non-3GPP" should be used. In addition, the SM Request includes the two PDU session identities provided by the UE 205 which further indicate that the UE 205 wishes to establish an MA-PDU session. In certain modalities, the SM Request also includes a multiple access parameter to indicate whether a multiple access data connection (here an MA-PDU) should be established. Note that the multiple access parameter is redundant when the UE 205 provides two PDU session identities.
[0075] [0075] SMF 146 selects a PCF (here PCF 148) and establishes a new session with the selected PCF 148, as usual (see operation 506). Subsequently, SMF 146 retrieves the multiple access routing rules PCF 148 that must be applied in UE 205 and UPF-A 143, in order to determine how to route uplink and downlink traffic, respectively, in the two secondary PDU sessions . These multiple access routing rules are also known as "traffic routing rules". As used in this document, traffic routing rules refer to the rules provided to remote units 105 over the mobile main network 103. Traffic routing rules are used by the UE 205 to select access when initiating a new data flow. As an example, the multiple access routing rule may indicate "select daughter PDU session t2 for app-x" or "select daughter PDU session * 2 for non-IMS traffic between 9 am and 5 pm". As another example, a multiple access routing rule can direct HTTP traffic to the child PDU * $ 2 session and voice over IP traffic to the child PDU t1 session.
[0076] [0076] SMF 146 can also recover from multiple access QoS rules PCF 148. Multiple access QoS rules include QoS rules that must be applied over the 5G RAN 215 (for example, the 3GPP access network) and rules QoS that must be applied over a non-3GPP access network. The purpose of the QoS rules applied to an access network is to allow traffic on that access network to be transported with different QoS characteristics, for example, different priority, different guaranteed bit rate, etc.
[0077] [0077] After communicating with PCF 148, SMF 146 starts the establishment of the user plan for the daughter PDU session that uses a non-3GPP access network (see operation 508). Here, SMF 146 sends a session establishment request (see operation 510) to the second UPF 142 (serving N3IWF 135) and receives an acknowledgment in response (see operation 512). SMF 146 also sends a session establishment request (see operation 514) to UPF anchor 143 and receives an acknowledgment in response (see operation 516).
[0078] [0078] Next, SMF 146 sends an SM request to AMF 145 (see operation 518) with a new parameter "Access network type = not 3GPP" to indicate to AMF 145 that the included N2 SM information must be sent for the non-3GPP access network (and not for the 3GPP access network from which the "Request to establish a PDU session" was received). Note that this SM request message does not contain a NAS message for the UE 205 (there is no Container N1l SM). This is because the SM Request message is not a response to the previous AMF SM request (for example, the request initiated by the UE), but it is a new SM request initiated by SMF 146.
[0079] [0079] The AMF 145 sends the N2 SM information, that is, a PDU session request message, to the N3IWF 135 (see operation 520). The PDU session request message includes the QoS profile (s) to be applied on the non-3GPP access network, each determined from the QoS rules to be applied on the non-3GPP access network, provided by the PCF 148 in operation 506. In addition, N3IWF 135 receives the PDU IDU-2 session that was provided by UE 205 in operation 502 and was associated with the non-3GPP access network.
[0080] [0080] In response, N3IWF 135 establishes one or more child security associations (s) IPsec (SAs) with UE 205 (see operation 522). Each IPsec SA carries one or more QoS streams for the child PDU session established on the non-3GPP access network (for example, the second child PDU session 230). Each QoS flow is associated with a QoS profile received by N3IWF 135 in the PDU Session Request message. The N3IWF 135 sends a PDU session request confirmation message to the AMF 145 (see operation 524) and the AMF 145 sends an SM request confirmation message to the SMF 146 (see operation 526). SMF 146 also sends a session change request to the second UPF 142 (see operation 528) and receives a confirmation message in response (see operation 530).
[0081] [0081] Continuing in Figure 5B, SMF 146 begins to establish the user plan for the 3GPP daughter PDU session (for example, the first daughter PDU session 225), which uses the 3GPP access network (see operation 532) . Here, SMF 146 sends a session establishment request (see operation 534) to the first UPF 141 (serving the 5G RAN 215) and receives an acknowledgment in response (see operation 536).
[0082] [0082] SMF 146 also sends a second session establishment request to the UPF anchor 143 (see operation 538) and receives a second confirmation in response (see operation 540). With the second session establishment request, SMF 146 provides multiple access routing rules for UPF anchor 143 (see operation 538). As discussed above, anchor UPF 143 uses multiple access routing steps to determine how to route downlink traffic in the two secondary sessions of the PDU. SMF 146 also provides a "Linked PDU Session" parameter that informs anchor UPF 143 to associate the new PDU session with the previously established PDU session (for example, in operation 514). This parameter indicates that anchor UPF 143 should consider PDU sessions identified as child PDU sessions of the same MA-PDU session and apply multiple access routing rules to route downlink traffic in those child PDU sessions.
[0083] [0083] The SMF 146 then sends an SM request confirmation message to the AMF 145 (see operation 542) to respond to the SM request in the operation
[0084] [0084] Returning to Figure 5B, the message "Acceptance of establishment of PDU session" is the response to the message "Request for establishment of PDU session" sent by UE 205 in operation 502. In certain modalities, the message "Acceptance of establishment of PDU session" PDU Session "can include a mode parameter that indicates the negotiated mode of operation of the MA-PDU session. This mode can be the same or different from the mode requested by the UE 205. For example, the UE 205 can request active / standby mode, with the "active" daughter being the daughter PDU session on the non-3GPP access network, but the you can decide to change the "active" daughter to the daughter PDU session on the 3GPP access network.
[0085] [0085] The AMF 145 sends the N2 SM information, that is, a PDU session request message, to the 5G RAN 215 (see operation 544). The PDU session request message includes the QoS profiles to be applied to the 5G RAN 215 (for example, the 3GPP access network), each profile determined from the QoS rules to be applied to the 3GPP access network, as provided PCF 148 in operation 506. In addition, the 5G RAN 215 receives the PDU Session
[0086] [0086] In response, the 5G RAN 215 sends a "PDU Session Establishment Acceptance" message to the UE 205. In addition, the 5G RAN 215 and the UE 205 establish one or more Data Radio Bearers (DRBs), each DRB associated with one or more QoS rules (for example, to transfer traffic corresponding to those QoS rules). Each DRB carries one or more QoS streams to the child PDU session over the 3GPP access network (for example, the first daughter PDU session 225). Each QoS flow is associated with a QoS profile sent to the 5G RAN 215.
[0087] [0087] The 5G RAN 215 sends a confirmation message to AMF 145 (see operation 548) and AMF 145 sends an SM request message with N2 information to SMF 146 (see operation 550). SMF 146 sends a session change request to the first UPF 141 (see operation 552) and receives a confirmation message in response (see operation 554). Procedure SMF 146 sends an SM request confirmation message to AMF 145 and network procedure 500 ends.
[0088] [0088] Note that the DRBs established in the 3GPP access network (for example, the 5G RAN 215) serve the same purpose as the daughter IPsec SAs established in the non-3GPP access network: both provide several communication carriers with different communication characteristics. QoS. In addition, while Figure 5 shows the sequential establishment of the daughter PDU sessions, in other modalities, the two daughter PDU sessions are established in parallel.
[0089] [0089] Figure 6 represents a network procedure
[0090] [0090] The network procedure 600 starts when the UE 205 wishes to establish a MA-PDU session through both access networks and sends a NAS message to the AMF 145 that includes a "Request for establishing a PDU session" (see operation 602 ). In the modalities of Figure 6A, the NAS message is sent via RAN 5G 215 (for example, the 3GPP access network), but in other modalities the NAS message can be sent via the non-3GPP access network. The NAS message includes a single PDU session identity and a multiple access parameter indicating that the UE 205 wants to establish a multiple access PDU session. This contrasts with the conventional NAS messages sent to the establishment of the PDU session that does not have a multiple access parameter.
[0091] [0091] The NAS message sent by the UE 205 can also include other information, such as the requested DNN (data network name), the type of slice requested, etc. In some embodiments, the message "Request to establish a PDU session" may include a mode parameter that indicates the requested operation mode of the MA-PDU session. For example, the mode parameter can indicate that the UE 205 prefers the MA-PDU session to operate in active / standby mode, with the child PDU session on a non-3GPP access network to be the "active" daughter and the PDU session daughter on the 5G RAN 215 to be The daughter "on hold". As another example, the UE 205 may prefer that the daughter PDU session on the 5G RAN 215 is the "active" daughter and the daughter PDU session on the non-3GPP access network is the "waiting" daughter.
[0092] [0092] In active / standby mode, all traffic from the MA-PDU session is transferred through the "active" daughter PDU session while the other daughter PDU session (the "waiting" daughter) does not carry any traffic. When the "active" daughter PDU session is unavailable on the UE 205 (for example, due to a lack of radio signal), it becomes a "waiting" daughter and the UE 205 transfers all traffic from the MA-PDU session to the other daughter PDU session that becomes the "active" daughter. When the network receives traffic from the UE 205 in a "waiting" child PDU session, it changes that child PDU session to "active". When the MA-PDU session operates in active / standby mode, it is not necessary to apply any multiple access routing rules (discussed below).
[0093] [0093] Next, AMF 145 selects an SMF 146 and sends an SM request (for example, a first SM request) to SMF 146 (see operation 604). The SM request includes the "PDU Session Establishment Request" received from the UE 205. The SM request also includes an Access Network Type parameter. Here, this parameter has the value "Type of access network = 3GPP" to indicate to SMF 146 that the session establishment request
[0094] [0094] In addition, the SM request includes the identity of the PDU session and the multiple access indicator provided by the UE 205. Note that in network procedure 600 the same PDU session ID is used for both access networks. In certain embodiments, the SM Request also includes a multiple access parameter to indicate to SMF 146 whether a multiple access data connection (here an MA-PDU) should be established.
[0095] [0095] SMF 146 selects and retrieves PCF 148 multiple access routing rules and multiple access QoS rules, as described in operation 506. SMF 146 also starts establishing the user plan for the child PDU session it uses non-3GPP access network (see operation 508), sends a Session Establishment Request (see operation 510) to the second UPF 142 (serving N3IWF 135) and receives an acknowledgment in response (see operation 512). SMF 146 also sends a session establishment request (see operation 514) to UPF anchor 143 and receives an acknowledgment in response (see operation 516).
[0096] [0096] Next, SMF 146 sends an SM request to AMF 145 (see operation 518) with a new parameter "Access network type = not 3GPP" to indicate to AMF 145 that the included N2 SM information must be sent for the non-3GPP access network (and not for the 3GPP access network from which the "PDU session establishment request" NAS was received). Again, this SM request message does not contain a NAS message for the UE 205 (there is no N1l SM container), as it is not a response to the previous AMF SM request.
[0097] [0097] AMF 145 sends N2 SM information as a PDU session request message to N3IWF 135 (see operation 620). The PDU session request message includes the QoS profile (s) to be applied on the non-3GPP access network, each determined from the QoS rules to be applied on the non-3GPP access network, provided by the PCF 148 in operation 506. In addition, N3IWF 135 receives the only PDU session ID that was provided by UE 205 in operation 602.
[0098] [0098] In response, N3IWF 135 establishes one or more child security associations (s) IPsec (SAs) with UE 205 (see operation 622). Each IPsec SA carries one or more QoS streams for the child PDU session established on the non-3GPP access network (for example, the second child PDU session 230). The N3IWF 135 sends a PDU session request confirmation message to the AMF 145 (see operation 524) and the AMF 145 sends an SM request confirmation message to the SMF 146 (see operation 526). SMF 146 also sends a session change request to the second UPF 142 (see operation 528) and receives a confirmation message in response (see operation 530).
[0099] [0099] Continuing in Figure 6B, SMF 146 begins the establishment of the user plan for the daughter PDU session over 3GPP (for example, the first daughter PDU session 225), which uses the 3GPP access network (see operation 532) . Here, SMF 146 sends a session establishment request (see operation 534) to the first UPF 141 (serving the 5G RAN 215) and receives an acknowledgment in response (see operation 536). SMF 146 also sends a second session establishment request to UPF anchor 143 (see operation 538) and receives a second acknowledgment in response (see operation 540).
[00100] [00100] The SMF 146 then sends an SM request confirmation message to the AMF 145 (see operation 542) to respond to the SM request in the operation
[00101] [00101] AMF 145 sends N2 SM information as a PDU session request message, to the 5G RAN 215
[00102] [00102] In response, the 5G RAN 215 sends a "PDU Session Establishment Acceptance" NAS to the UE 205. In addition, the 5G RAN 215 and UE 205 establish one or more Data Radio Bearers (DRBs), each DRB associated with one or more QoS rules (for example, to transfer traffic corresponding to those QoS rules). Each DRB carries one or more QoS streams to the child PDU session over the 3GPP access network (for example, the first daughter PDU session 225). Each QoS flow is associated with a QoS profile sent to the 5G RAN 215.
[00103] [00103] The 5G RAN 215 sends a confirmation message to AMF 145 (see operation 548) and AMF 145 sends an SM request message with N2 information to SMF 146 (see operation 550). SMF 146 then sends a session change request to the first UPF 141 (see operation 552) and receives a confirmation message in response (see operation 554). Procedure SMF 146 sends an SM request confirmation message to AMF 145 and network procedure 600 ends.
[00104] [00104] Note that the DRBs established in the 3GPP access network (for example, the 5G RAN 215) serve the same purpose as the daughter IPsec SAs established in the non-3GPP access network: both provide several communication carriers with different communication characteristics. QoS. While Figures 6A-B show the sequential establishment of the daughter PDU sessions, in other modalities, the two daughter PDU sessions are established in parallel. Also note that as a single PDU session identity is shared by the child PDU sessions, whenever the UE 205 or the network wants to perform an operation on a child PDU session (for example, changing the QoS rules of the $ 2 daughter PDU session) , the identity of the PDU session and the corresponding access network type must be provided to identify the appropriate child PDU session.
[00105] [00105] Figure 7 represents a network procedure 700 to establish a multiple access data connection, according to disclosure modalities. The network procedure 700 is a procedure initiated on the network to establish a multiple access data connection from a single request to establish a data connection. The network procedure involves the UE 205, the 5G RAN 215, the N3IWF 135, the AME 145, the SMF 146, the first UPF 141, the second UPF 142, the UPF 143 anchor and the PCF 148 Here, the UE 205 is connected simultaneously to the mobile communication network via a 3GPP access network (here, the 5G RAN 215) and a non-3GPP access network (such as WLAN 220).
[00106] [00106] The network procedure 700 begins and the UE 205 requests a normal PDU session (ie, single access network) (see operation 702). In the modalities of Figure 7, the NAS message is sent through RAN 5G 215 (for example, the 3GPP access network), but in other modalities the NAS message can be sent through the non-3GPP access network. The NAS message includes a single PDU session identity, but does not contain any indication that the UE 205 wants to establish a multiple access PDU session. The NAS message sent by the UE 205 can also include other information, such as the requested DNN (data network name), the type of slice requested, etc.
[00107] [00107] Then, AMF 145 selects an SMF 146 and sends the SM request to SMF 146 and includes the new multiple access parameter to indicate to SMF 146 that the UE 205 is connected to both the 3GPP access network and the network non-3GPP access (704). The SM request includes the "PDU Session Establishment Request" received from the UE 205. The SM request also includes an Access Network Type parameter. Here, this parameter has the value "Type of access network = 3GPP" to indicate to SMF 146 that the request to establish a PDU session was received by the access network 3GPP (for example, the 5G RAN 215). Where the PDU Session Establishment Request is received by the non-3GPP access network, then a value "Type of access network = non-3GPP" should be used.
[00108] [00108] Based on the multiple access parameter and local information or policies, SMF 146 decides to establish an MA-PDU session instead of the single access network PDU session requested by the UE 205 (see operation 706). This decision can be made when SMF 146 wants, for example, to download part of the data traffic from the requested PDU session to a non-3GPP access network. For example, when UE 205 requests in operation 702 to establish a PDU session through the access network
[00109] [00109] Before making this decision, SMF 146 can interact with UDM 149 to determine if the UE 205 signature allows the establishment of an MA-PDU session for the requested DNN. In addition, SMF 146 may decide to establish an MA-PDU session based on information retrieved from PCF 148 in operation 708. In that case, the decision to establish an MA-PDU session (for example, operation 706) is made after the operation 708.
[00110] [00110] As discussed, SMF 146 interacts with PCF 148 (for example, establishes a new PDU-CAN session) and can retrieve multiple access routing rules that must be applied on UE 205 and on UPF anchor 143 in order to determine how to route uplink and downlink traffic, respectively, in the two child PDU sessions (see operation 708). SMF 146 can also recover from multiple PCF access QoS rules, that is, QoS rules that must be applied over the 3GPP access network and QoS rules that must be applied over the non-3GPP access network.
[00111] [00111] Then, SMF 146 begins to establish the daughter PDU session d% 2 on a non-3GPP access network, as discussed above in operations 508-518. AMF 145 sends the N3IWF 135 the QoS profile (s) to be applied in non-3GPP access networks, each determined based on the QoS rules to be applied in non-3GPP access networks, provided by PCF. In addition, the N3IWF 135 receives the unique PDU session ID that was provided by the UE 205 in step 1.
[00112] [00112] Then, the UE 205 and the N3IWF 135 establish one or more daughter IPsec SAs (see operation 722). Based on the received PDU session ID, the UE 205 determines that these child IPsec SAs are part of the PDU session requested in operation 702. In other words, the UE 205 determines that the network has decided to establish an MA-PDU session instead of the session Single access network PDU requested. The N3IWF 135 sends a PDU session request confirmation message to the AMF 145 (see operation 524) and the AMF 145 sends an SM request confirmation message to the SMF 146 (see operation 526). SMF 146 also sends a session change request to the second UPF 142 (see operation 528) and receives a confirmation message in response (see operation 530).
[00113] [00113] The network procedure 700 continues to establish the user plan for the daughter PDU session via 3GPP (for example, the first daughter PDU session 225), which uses the 3GPP access network as represented in Figure 6B and described above with reference to Figure 6B. In short, SMF 146 sends an SM request confirmation message to AMF 145 (for example, operation 542), AMF 145 sends a PDU session request to the 5G RAN 215 that includes the unique PDU session ID ( 644) and UE 205 and 5G RAN 215 establish DRBs (operation 646).
[00114] [00114] While the Figures show the sequential establishment of the daughter PDU sessions, in other modalities, the two daughter PDU sessions are established in parallel. Also note that as a single PDU session identity is shared by the child PDU sessions, whenever the UE 205 or the network wants to perform an operation on a child PDU session (for example, changing the QoS rules of the f2 daughter PDU session) , the identity of the PDU session and the corresponding access network type must be provided to identify the appropriate child PDU session.
[00115] [00115] Figure 8 represents a model of UE 800, according to disclosure modalities. The UE 800 model shows the UE 205 after the multiple access data connection (for example, the MA-PDU session) is established. As shown, the IP layer 201 generates an uplink data packet (UL data) that is passed to the virtual interface layer 203. As described above, the virtual interface layer 203 is a layer that exposes a single interface to the upper layers, for example, a single IP interface for layer IP 201 when the MA-PDU session is of the IP type. The virtual interface layer 203 applies the multiple access routing steps 803 that were received during the establishment of the MA-PDU session and determine whether the UL data packet should be routed through the child PDU session via 3GPP access or through the session. Daughter PDU over non-3GPP access.
[00116] [00116] Each child PDU session has its own QoS rules (for example, QoS rules for non-3GPP 805 and QoS rules for 3GPP 807), as shown in Figure 8. The UL data packet routed to a daughter PDU session it is first compared to a QoS rule and associated with the QoS Flow Identifier (QFI) of the corresponding QoS rule. Then, based on the associated QFI, it is routed to a corresponding DRB (for the 3GPP daughter PDU session) or to a corresponding daughter IPsec SA (for the non-3GPP PDU session).
[00117] [00117] Figure 9 represents a 900 method for establishing a multiple access data connection, according to disclosure modalities. In some embodiments, method 900 is performed by a device, such as the SMF 146 and / or the session management appliance 400 In certain embodiments, method 900 can be performed by a processor executing program code, for example, a microcontroller, microprocessor, CPU, GPU, auxiliary processing unit, FPGA or similar.
[00118] [00118] Method 900 begins with the receipt of 905 a first request for session management through an access management function in a mobile communication network. Here, the first session management request contains a second session management request sent by a remote unit that communicates with the mobile communication network through a first access network and a second access network. In one embodiment, the second session management request is sent through the second access network.
[00119] [00119] In some embodiments, the first session management request contains an indication to establish a multiple access data connection to the remote unit through a first access network and a second access network. In one embodiment, the indication to establish a multiple access data connection to the remote unit via a first access network and a second access network contains a first session identifier associated with the first access network and a second session identifier associated with the second access network. In another embodiment, the indication for establishing a multiple access data connection to the remote unit via a first access network and a second access network contains a first session identifier and a multiple access parameter.
[00120] [00120] In some modalities, the second session management request is a request from the remote unit to establish a data connection through a single access network, and the first session management request includes an indication that the remote unit it has simultaneous connections to the first access network and the second access network. In such embodiments, receiving 905 the first session management request may include understanding determining the establishment of a multiple access data connection in response to receiving the first session management request. In certain embodiments, the second session management request includes a mode parameter, the mode parameter contains a requested operation mode for the multiple access data connection.
[00121] [00121] In certain modalities, receipt 905 of the first session management request includes consulting a policy control function for at least one of the following: multiple access routing rules and multiple access QoS rules associated with the unit remote. Here, multiple access QoS rules include QoS rules for the first access network and QoS rules for the second access network. The multiple access routing rules tell you how to route multiple access data connection traffic through the first access network and the second access network.
[00122] [00122] Under certain modalities, the first access network is an access network not defined by 3GPP ("non-3GPP access") and the second access network is an access network defined by 3GPP ("3GPP access"). In such embodiments, the second session management request may be a request to establish a Packet Data Unit ("PDU") session.
[00123] [00123] Method 900 includes sending 910 a first request to the access management function to establish a first data path for the multiple access data connection by the first access network, in response to the first session management request. In certain embodiments, sending 910 the first request to the access management function to establish the first data path for the multiple access data connection includes sending a third session management request without a Session Management container. Embedded N1l. Here, the third session management request indicates that the access management function is to send the first request to the first access network.
[00124] [00124] In some embodiments, sending 910 of the first request to the access management function includes sending a session establishment request to the common user plan function anchoring the first and second data paths, the request session establishment including multiple access routing rules and an indication that the first and second data paths are for a multiple access data connection.
[00125] [00125] In one embodiment, sending 910 of the first request to the access management function includes consulting a data management function to determine whether a network subscription from the remote unit allows a multiple access connection in response to receiving the first request for session management and determination to establish a multiple access data connection based on the remote unit's network signature. In another embodiment, sending 910 a first request to the access management function includes querying a policy control function for at least one of the multiple access routing rules and multiple access QoS rules associated with the data connection requested in response upon receipt of the first session management request, and determine to establish the multiple access data connection based on at least one of the multiple access routing rules and multiple access QoS rules received from the policy control function.
[00126] [00126] Method 900 includes sending 915 a second request to the access management function to establish a second data path for the multiple access data connection through the second access network, in response to the first session management request. Here, the first data path and the second data path are anchored in a common user plan network function in the mobile communication network. In certain embodiments, sending 915 the second request to the access management function to establish the second data path for the multiple access data connection includes sending a response to the first session management request, where the response contains an embedded N1 Session Management container. In one embodiment, the embedded Nl Session Management container includes a PDU session establishment access message that contains multiple access routing rules and multiple access quality of service ("QoS") rules associated with the data connection. multiple access. Method 900 ends.
[00127] [00127] Figure 10 represents a method 1000 to establish a multiple access data connection, according to disclosure modalities. In some embodiments, method 1000 is performed by a device, such as remote unit 105, UE 205, and / or the UE device
[00128] [00128] Method 1000 starts with communication 1005 with a mobile communication network through a first access network and a second access network. Method 1000 includes transmitting a 1010 request to establish a data connection. In some modalities, the first access network is an access network not defined by 3GPP
[00129] [00129] In some modalities, the request to establish a data connection includes an indication to establish the data connection through the first and second access networks. In one embodiment, the indication for establishing the data connection through the first and second access networks comprises a first session identifier associated with the first access network and a second session identifier associated with the second access network. In another embodiment, the indication for establishing the data connection on the first and second access networks comprises a first session identifier and a multiple access parameter, where the first session identifier is associated with the first access network and the second access network.
[00130] [00130] In certain embodiments, transmission 1010 of the request to establish a data connection comprises transmission through the second access network. In certain embodiments, the request to establish a data connection contains a session identifier associated with the second access network and does not contain a session identifier associated with the first access network.
[00131] [00131] Method 1000 includes receiving 1015 a first request to configure a first data bearer for the data connection through the first access network in response to the request. In certain embodiments, the first request to configure a first data bearer for the data connection over the first access network includes the session identifier associated with the second access network. In other embodiments, receiving 1015 the first request to configure a first data carrier may include determining that the request by the second access network to establish a data connection initiated the establishment of a multiple access data connection by the first access network and by the second access network, for example, determined based on the first request, including the session identifier associated with the second access network.
[00132] [00132] Method 1000 includes receiving 1020 a second request to configure a second data carrier for the data connection by the second access network in response to the request. Here, the first data carrier and the second data carrier are used to carry traffic from the data connection. Method 1000 ends.
[00133] [00133] Modalities can be practiced in other specific ways. The described modalities should be considered in all aspects only as illustrative and not restrictive. The scope of the invention is therefore indicated by the appended claims and not by the previous description. All changes that fall within the meaning and equivalence range of the claims must be adopted within their scope.

权利要求:
Claims (42)
[1]
1. Device, characterized by the fact that it comprises: a transceiver that communicates with one or more network functions in a mobile communication network; and a processor that: receives a first session management request via an access management function, the first session management request containing a second session management request sent by a remote unit that communicates with the network mobile communication through a first access network and a second access network, the second session management request being sent by the second access network; sends a first request to the access management function to establish a first data path for a multiple access data connection over the first access network, in response to the first session management request; and sends a second request to the access management function to establish a second data path for the multiple access data connection through the second access network, in response to the first session management request, where both the first path data and the second data path is anchored in a common user plan network function in the mobile communication network.
[2]
2. Apparatus according to claim 1, characterized by the fact that the first session management request contains an indication for establishing a multiple access data connection to the remote unit via a first access network and a second network access.
[3]
3. Apparatus according to claim 2, characterized by the fact that the indication to establish a multiple access data connection to the remote unit via a first access network and a second access network contains a first session identifier associated with the first access network and a second session identifier associated with the second access network.
[4]
4, Apparatus according to claim 2, characterized in that the indication to establish a multiple access data connection to the remote unit via a first access network and a second access network contains a first session identifier and a multiple access parameter, where the first session identifier is associated with the first access network and the second access network.
[5]
5. Apparatus, according to claim 1, characterized by the fact that the processor still queries a policy control function for at least one of the multiple access routing rules and multiple access quality of service rules ("QoS" ) associated with the remote unit.
[6]
6. Apparatus, according to claim 5, characterized by the fact that the multiple access QoS rules comprise QoS rules for the first access network and QoS rules for the second access network, in which the routing rules Multiple access networks indicate how to route multiple access data connection traffic through the first access network and the second access network.
[7]
7. Apparatus, according to claim 5, characterized by the fact that the processor still sends a session establishment request to the common user plan function anchoring the first and second data paths, the session establishment request including multiple access routing rules and an indication that the first and second data paths are for a multiple access data connection.
[8]
8. Apparatus, according to claim 1, characterized by the fact that the first access network is an access network not defined by 3GPP ("non-3GPP access") and the second access network is an access network defined by 3GPP ("3GPP access"), and where the second session management request is a Packet Data Unit ("PDU") session establishment request.
[9]
9. Apparatus, according to claim 8, characterized by the fact that sending the first request to the access management function to establish the first data path for the multiple access data connection comprises sending a third request for access. session management without an embedded N1 Session Management container, the third session management request indicating that the access management function is to send it to the first access network, and in which the second request is sent to the access management function to establish the second data path for the multiple access data connection comprises sending a response to the first session management request, where the response contains an embedded N1 Session Management container.
[10]
10. Device, according to claim 9, characterized by the fact that the N1 Session Management container includes an access message to the establishment of the PDU session that contains multiple access routing rules and quality of service rules ("QoS ") multiple access data associated with the multiple access data connection.
[11]
11. Apparatus, according to claim 1, characterized by the fact that the second session management request is a request from the remote unit to establish a data connection through a single access network, and the first request for management management The session includes an indication that the remote unit has simultaneous connections to the first access network and the second access network, where the processor still determines to establish a multiple access data connection in response to receiving the first session management request. .
[12]
12. Device according to claim 11, characterized by the fact that the processor also consults a data management function to determine whether a network subscription from the remote unit allows a multiple access connection in response to the receipt of the first request for session management, and where the processor determines to establish a multiple access data connection based on the remote unit’s network subscription.
[13]
13. Apparatus, according to claim 11, characterized by the fact that the processor still queries a policy control function for at least one of the multiple access routing rules and the multiple access quality of service rules ("QoS ") associated with the data connection requested in response to receiving the first session management request, and where the processor determines to establish the multiple access data connection based on at least one of the multiple access routing rules and access rules. Multiple access QoS received from the policy control function.
[14]
14. Apparatus, according to claim 1, characterized by the fact that the second session management request comprises a mode parameter, the mode parameter containing a requested operation mode for the multiple access data connection.
[15]
15. Method, characterized by the fact that it comprises: receiving a first session management request via an access management function on a mobile communication network, the first session management request containing a second session management request sent by a remote unit that communicates with the mobile communication network through a first access network and a second access network, the second session management request being sent through the second access network; send a first request to the access management function to establish a first data path for a multiple access data connection over the first access network, in response to the first session management request; and sending a second request to the access management function to establish a second data path for the multiple access data connection over the second access network, in response to the first session management request, where the first data path and the second data path is anchored in a common user plan network function in the mobile communication network.
[16]
16. Method, according to claim 15, characterized by the fact that the first session management request contains an indication to establish a multiple access data connection to the remote unit through a first access network and a second network access.
[17]
17. Method according to claim 16, characterized in that the indication for establishing a multiple access data connection to the remote unit via a first access network and a second access network contains a first session identifier associated with the first access network and a second session identifier associated with the second access network.
[18]
18. Method according to claim 16, characterized in that the indication for establishing a multiple access data connection to the remote unit via a first access network and a second access network contains a first session identifier and a multiple access parameter, where the first session identifier is associated with the first access network and the second access network.
[19]
19. Method, according to claim 15, characterized by the fact that it also includes consulting a policy control function for at least one of: multiple access routing rules and multiple access quality of service rules ("QoS" ) associated with the remote unit.
[20]
20. Method, according to claim 19, characterized by the fact that the multiple access QoS rules comprise QoS rules for the first access network and QoS rules for the second access network, in which the routing rules Multiple access networks indicate how to route multiple access data connection traffic through the first access network and the second access network.
[21]
21. Method, according to claim 19, characterized by the fact that it also comprises sending a session establishment request to the common user plan function anchoring the first and second data paths, the session establishment request including the multiple access routing rules and an indication that the first and second data paths are for a multiple access data connection.
[22]
22. Method according to claim 15, characterized by the fact that the first access network is an access network not defined by 3GPP ("non-3GPP access") and the second access network is an access network defined by 3GPP ("3GPP access"), and where the second session management request is a Packet Data Unit ("PDU") session establishment request.
[23]
23. Method according to claim 22, characterized by the fact that sending the first request to the access management function to establish the first data path for the multiple access data connection comprises sending a third request for access. session management without an embedded N1 Session Management container, the third session management request indicating that the access management function is to send it to the first access network, and in which the second request is sent to the access management function to establish the second data path for the multiple access data connection comprises sending a response to the first session management request, where the response contains an embedded N1 Session Management container.
[24]
24. Method, according to claim 23, characterized by the fact that the embedded Nl Session Management container includes an access message to the establishment of the PDU session that contains multiple access routing rules and quality of service rules (" Multiple access QoS ") associated with the multiple access data connection.
[25]
25. Method, according to claim 15, characterized by the fact that the second session management request is a request from the remote unit to establish a data connection through a single access network, and the first request for management management The session includes an indication that the remote unit has simultaneous connections to the first access network and the second access network, the method further comprising determining to establish a multiple access data connection in response to receiving the first session management request. .
[26]
26. Method, according to claim 25, characterized by the fact that it further comprises consulting a data management function to determine whether a network subscription of the remote unit allows a multiple access connection in response to the receipt of the first management request session, and determines to establish a multiple access data connection based on the remote unit's network subscription.
[27]
27. Method, according to claim 25, characterized by the fact that it also includes consulting a policy control function for at least one of the multiple access routing rules and the multiple access quality of service rules ("QoS" ) associated with the data connection requested in response to receiving the first session management request, and in which it determines to establish the multiple access data connection based on at least one of the multiple access routing rules and access QoS rules multiple received from the policy control function.
[28]
28. Method, according to claim 15, characterized by the fact that the second session management request comprises a mode parameter, the mode parameter containing a requested operation mode for the multiple access data connection.
[29]
29. Apparatus, characterized by the fact that it comprises: a first transceiver that communicates with a mobile communication network through a first access network; a second transceiver that communicates with a mobile communication network through a second access network; and a processor that: transmits a request, through the second access network, to establish a data connection; receives a first request to configure a first data carrier for the data connection on the first access network in response to the request, and receives a second request to configure a second data carrier for the data connection on the second access network in response to the request, where the first data bearer and the second data bearer are used to carry traffic from the data connection.
[30]
30. Apparatus according to claim 29 characterized by the fact that the request to establish a data connection comprises an indication to establish the data connection through the first and second access networks.
[31]
31. Apparatus according to claim 30, characterized in that the indication for establishing the data connection through the first and second access networks comprises a first session identifier associated with the first access network and a second access identifier. session associated with the second access network.
[32]
32. Apparatus according to claim 30,
characterized by the fact that the indication to establish the data connection in the first and second access networks comprises a first session identifier and a multiple access parameter, in which the first session identifier is associated with the first access network and the second access network.
[33]
33. Apparatus according to claim 29 characterized by the fact that the request to establish a data connection contains a first session identifier associated with the second access network and does not contain an indication to establish the data connection through the first and the second access networks, where the first request to configure a first data carrier for the data connection on the first access network and the second request to configure a second data carrier for the data connection on the second access network include the first session identifier, where the processor determines that the request through the second access network to establish a data connection initiated the establishment of a multiple access data connection through the first access network and the second access network.
[34]
34. Apparatus according to claim 29 characterized by the fact that the first access network is an access network not defined by 3GPP ("non-3GPP access") and the second access network is an access network defined by 3GPP ("3GPP access"), and where the request to establish a data connection is a request to establish a
Packet Data Unit ("PDU").
[35]
35. Apparatus according to claim 29 characterized by the fact that the request to establish a data connection comprises mode parameter, the mode parameter containing a requested operation mode for a multiple access data connection.
[36]
36. Method, characterized by the fact that it comprises: communication with a mobile communication network through a first access network and a second access network; transmit a request, through the second access network, to establish a data connection; receiving a first request to configure a first data bearer for the data connection through the first access network in response to the request; and receiving a second request to configure a second data bearer for the data connection via the second access network in response to the request, where the first data bearer and the second data bearer are used to carry traffic from the data connection. Dice.
[37]
37. Method according to claim 36, characterized in that the request to establish a data connection comprises an indication to establish the data connection through the first and second access networks.
[38]
38. Method according to claim 37, characterized in that the indication for establishing the data connection through the first and second access networks comprises a first session identifier associated with the first access network and a second access identifier. session associated with the second access network.
[39]
39. Method according to claim 37, characterized by the fact that the indication for establishing the data connection in the first and second access networks comprises a first session identifier and a multiple access parameter, in which the first identifier session is associated with the first access network and the second access network.
[40]
40. Method according to claim 36, characterized in that the request through the second access network to establish a data connection contains a first session identifier associated with the second access network and does not contain an indication to establish the data connection through the first and second access networks, where the first request to configure a first data bearer for the data connection on the first access network and the second request to configure a second data bearer for the data connection data on the second access network includes the first session identifier, the method further comprises determining that the request via the second access network to establish a data connection initiated the establishment of a multiple access data connection through the first access network and the second access network.
[41]
41. Method, according to claim 36, characterized by the fact that the first access network is an access network not defined by 3GPP ("non-3GPP access") and the second access network is an access network defined by 3GPP ("3GPP access"), and where the request to establish a data connection is a Packet Data Unit ("PDU") session request.
[42]
42. Method according to claim 36, characterized by the fact that the request to establish a data connection comprises a mode parameter, the mode parameter containing a requested mode of operation for a multiple access data connection.

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法律状态:
2021-11-03| B350| Update of information on the portal [chapter 15.35 patent gazette]|

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PCT/EP2017/067227|WO2019011398A1|2017-07-10|2017-07-10|Multi-access data connection in a mobile network|

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