A method of handling multi-access (MA) Protocol data unit (PDU) session handover is proposed. A UE and network can support Access Traffic Steering Switching and Splitting (ATSSS) functionalities to distribute traffic over 3GPP access and non-3GPP access for the established MA PDU session. An ATSSS-Supported UE first establishes a MA PDU Session on both 3GPP and non-3GPP access in a currently registered PLMN which is an ATSSS-Supported network. The UE then moves from the ATSSS-Supported network to an ATSSS-not-Supported network and finally reaches another ATSSS-Supported network. In one novel aspect, a solution is provided on how to handle the ongoing MA PDU Session with two accesses under handover scenarios between ATSSS-Supported and ATSSS-not-Supported networks. Furthermore, if the ongoing MA PDU Session cannot handover, a solution is provided on how to handle the MA PDU Session.

According to one configuration, a wireless network environment includes a first wireless network and a second wireless network. A mobile communication device in the wireless network environment receives first paging notifications directed to the mobile communication device from a first wireless base station such as operated by a first wireless network service provider. The mobile communication device receives second paging notifications directed to the mobile communication device from a second wireless base station such as operated by a second wireless network service provider. The wireless network environment provides improved paging over conventional techniques.

Systems, methods and computer software are disclosed for resolving multiple contexts for a User Equipment (UE) in a wireless network. In one embodiment a method includes maintaining, for a coordinating node hosting a first Radio Access Technology (RAT) controller and a second RAT controller simultaneously, a centrally maintained database; determining, based on the contents of the centrally maintained database, when the UE is registering with the second RAT controller while currently registered with the first RAT controller; and sending, by the second RAT controller, a deregistration command to the first RAT controller the UE was registered with, wherein context is freed and wherein resources held at both the coordinating node and at a base station are freed.

Systems, methods, and devices include techniques for establishing an enhanced multi-access protocol data unit (PDU) session in a multi-network environment. Various registration procedures may be used to allocate resources between a first network (e.g., a Mobile Network Operator (MNO) and a second network (e.g., a Mobile Virtual Network Operator (MVNO). For instance, a method includes sending by a wireless device to a network, indication(s) related to network capabilities of the wireless device. The indication(s) include whether the wireless device supports a multi-access PDU session comprising a first PDU session and a second PDU session. The first PDU session is established via a 3rd Generation Partnership Project (3GPP) access the second PDU session is established via a first non-3GPP. The indication(s) include whether the wireless device supports an enhanced multi-access PDU session comprising a third PDU session, wherein the third PDU session is established via a second non-3GPP access.

The embodiments of the application disclose a registration method, a terminal device and a network device. The method includes: when the terminal device is registered on a first network through a first access technology, acquiring, by the terminal device, first slice information; when the terminal device is registered on a second network through a second access technology, acquiring, by the terminal device, second slice information, where the second slice information and the first slice information are not mutually exclusive. The method, terminal device and network device of the embodiments of the present application can ensure that slices obtained by the terminal device over multiple access technologies are not mutually exclusive, thereby ensuring the progress of services.

Systems and methods are disclosed herein that relate to supporting Internet Protocol (IP) Multimedia Subsystem (IMS) routing with multiple IMS Protocol Data Unit (PDU) sessions over different core network slices. In one embodiment, a method comprises, at an Interrogating Call Session Control Function (I-CSCF), receiving a Session Initiation Protocol (SIP) invite message for an incoming session, where the SIP invite message comprises an IP Multimedia Public Identity (IMPU) of a target User Equipment (UE). The method further comprises, at the I-CSCF, sending, to a Home Subscriber Server (HSS), a query for Serving Call Session Control Functions (S-CSCFs) having registrations for the IMPU of the target UE and receiving, from the HSS, information that indicates two or more S-CSCFs having registrations for the IMPU of the target UE. The method further comprises, at the I-CSCF, forwarding the SIP invite message to at least one of the two or more S-CSCFs.

An electronic device is provided. The electronic device includes a processor, a plurality of SIMs connected to the at least one processor, wherein the at least one processor is configured to transmit or receive Internet packet data by using a first SIM, based on a first network and a first RAT, corresponding to the first SIM, when a second SIM supports a second RAT different from the first RAT, identify whether communication based on a second network and a second RAT, corresponding to the second SIM, can be performed during transmission or reception of the Internet packet data to or from the first network, and based on identifying that communication based on the second network and the second RAT, corresponding to the second SIM, can be performed, transmit or receive the Internet packet data based on the second network and the second RAT, corresponding to the second SIM.

The present application relates to devices and components including apparatus, systems, and methods for IMS registration in wireless networks.

Embodiments include systems and methods that may be performed by a processor of a multi-subscription wireless device for managing beam selection. Various embodiments may include determining a rotation angle between an orientation of a first beam of a first subscription and an orientation of a second beam of the first subscription, applying the rotation angle to a first beam of a second subscription to identify a second beam of the second subscription, and performing a tune-away operation comprising tuning a radio frequency (RF) resource of the multi-subscription wireless device to the second subscription and configuring spatial filter parameters of an antenna array to communicate via the identified second beam of the second subscription.

The present invention provides a method for WLAN aggregation control, comprising: receiving, by a base station, WLAN information of a UE, said WLAN information of the UE comprises one or more of the following: user preference information, WLAN information of a WLAN node with which the UE is being associated, WLAN information of a WLAN node reselected by the UE, de-association information of the UE with a WLAN node, WLAN enabling information of the UE, and WLAN disabling information of the UE; and determining, by the base station, whether WLAN aggregation is to be established or deleted for the UE according to the received WLAN information of the UE. With the present application, WLAN aggregation can be reasonably controlled. Also, the present invention provides a method by a terminal, comprising: identifying a connection status with a node in a second network, setting status information associated with the node based on the connection status, and transmitting, to a base station in a first network, a report message including the status information.