Described are a method and apparatus for controlling the power consumption of a terminal, and a storage medium. The method includes: recording the number of times a connection between a terminal and an auxiliary cell group fails, and where the number of times is greater than a preset threshold value, controlling, on the basis of a power consumption adjustment policy, the terminal to disable a dual-connection mode, wherein the terminal can support the dual-connection mode, and in the dual-connection mode, the terminal communicates with both a first base station and a second base station, the second base station being an auxiliary base station, and the auxiliary cell group being a group of serving cells associated with the auxiliary base station.

A primary access node adds a secondary access node to deliver wireless communication service to a User Equipment (UE). The primary access node comprises baseband circuitry and a radio. The radio wirelessly receives a measurement report from the UE that characterizes a radio metric for the secondary access node. The baseband circuitry determines insertion loss for the secondary access node and an add threshold for the secondary access node based on the insertion loss. The baseband circuitry determines an add value for the secondary access node based on the radio metric. When the add value exceeds the add threshold, the baseband circuitry transfers network signaling to the secondary access node to serve the UE and transfers user signaling to the UE over the radio. The UE attaches to the secondary access node and the secondary access node delivers the wireless communication service to the UE.

Provided is a method and apparatus for providing call function continuity in an electronic device. The electronic device may include: a first communication circuit configured to support new radio (NR) communication and/or long-term evolution (LTE) communication, a second communication circuit configured to support wireless LAN communication, and at least one processor operatively connected to the first communication circuit and the second communication circuit, wherein the processor is configured to control the electronic device to: register with a network of the NR communication via the first communication circuit; connect a call to an external device using the wireless LAN communication based on being in a state of being registered with the network of the NR communication; based on the call connection to the external device using the wireless LAN communication, restrict use of the NR communication; and based on the restriction of the use of the NR communication, register with a network of the LTE communication via the first communication circuit.

A user equipment (UE) is configured to establish network connections for long-term evolution (LTE) and new radio (NR) radio access technologies (RATS) in non-standalone (NSA) E-UTRA-NR dual connectivity (ENDC) operation. The UE includes a multi-antenna array for data and signaling transmissions and receptions over the LTE and NR connections. The UE determines a most efficient antenna of the multi-antenna array for an operating frequency band of the LTE and NR connections, wherein the most efficient antenna is determined based on at least one performance factor for the UE when using the antenna compared to other antennas of the multi-antenna array, evaluates one or more factors for determining whether the LTE RAT or the NR RAT is to use the most efficient antenna and transmits uplink data on the most efficient antenna via either the LTE RAT or the NR RAT based on the evaluated factors.

A system and method to identify different access names for discovering and learning service provider's Wi-Fi access networks in user's premises where user may have defined a customized SSID on said Wi-Fi Access Points, for increasing the likelihood for automatic Wi-Fi offload on service provider network thus enhancing user experience to dynamically offload a user equipment [202] and prevent revenue loss for the service provider by keeping the user always on its Network (either cellular or Wi-Fi). Furthermore, the method encompasses identifying of a parent service provider's user-defined Wi-Fi Access Network SSID(s), learning one or more information of connection between said SSID(s) and the UE [202], categorizing said SSID(s) and allowing automated offload to a selected SSID whenever the UE [202] is within its coverage.

A system for dynamically modifying a buffer in a network deploying multiple carriers is provided. Each carrier operating over the network utilizes a radio access technology (RAT). The system includes a network load monitoring processor that measures a network load on carriers using a first RAT to produce a measured value and a buffer management processor that receives the measured value, performs a comparison of the measured value with a predetermined value, and dynamically modifies a size of the buffer when the measured value exceeds the predetermined value.

Disclosed herein is an integrated core network of 5G and ATSC 3.0. The integrated core network of 5G and ATSC 3.0 includes multiple control plane entities and a user plane entity, and further includes an ATSC 3.0 gateway, thereby enabling multimedia content transmitted from the ATSC 3.0 gateway to the user plane entity under the control of the control entity to be delivered to user equipment over an ATSC 3.0 terrestrial network. The ATSC 3.0 gateway may include an ATSC 3.0 Control Plane Gateway (CP-GW) connected between the user plane entity and the multiple control plane entities and an ATSC 3.0 User Plane Gateway (UP-GW) connected to the user plane entity.

The present invention relates to methods and apparatus for providing backhaul wireless services using a plurality of different Radio Access Technologies. An exemplary method embodiment includes the steps of: determining a set of routes for the communication of data from a first wireless base station to a destination wireless base station over wireless backhaul communications links, the first wireless base station being an Integrated Access and Backhaul donor, receiving data of a first flow at the first wireless base station for communication to a first wireless user equipment device attached to the destination wireless base station; and selecting, at the first wireless base station, one or more of the routes of the set of routes from the first wireless base station to the destination wireless base station, the selection being based on multi-Radio Access Technology (multi-RAT) capability of wireless base stations of which a route is comprised.

A method for domain name resolution includes: requesting, by an access device, via a resolving request, an IP address based on a present domain name or a domain name based on a present IP address, wherein the access device is configured to have multipath access to a data network via at least two access paths; generating, by the access device, an initial domain name query based on the resolving request; duplicating, by the access device, the initial domain name query into at least two multiplied domain name queries; sending, by the access device, each of the at least two multiplied domain name queries to a respective name server; and receiving, by the access device, a domain name response comprising the requested IP address or the requested domain name from each respective name server.

A system, method, and computer-readable medium are disclosed for performing a connectivity handover operation. The connectivity handover operation includes: identifying a Wireless Wide Area Network (WWAN) link, the WWAN link having an associated WWAN location quality identifier; identifying a Wireless Local Area Network (WLAN) link, the WLAN link having an associated WLAN location quality identifier; monitoring the associated WWAN location quality identifier and the associated WLAN location quality indicator; determining whether the WWAN link should be activated based upon the associated WLAN location quality identifier; and, performing the connectivity handover operation based upon the determining.