Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may receive a vehicle-to-everything (V2X) packet. The UE may duplicate, at a protocol stack layer of the UE, the V2X packet to form a plurality of duplicated V2X packets, wherein each duplicated V2X packet is associated with a directional range. Numerous other aspects are provided.

A control method for an image output device includes performing wireless communication with a display device using a first frequency band and a second frequency band, acquiring communication traffic of the first frequency band and communication traffic of the second frequency band, and, when the communication traffic of the first frequency band is smaller than the communication traffic of the second frequency band, transmitting audio data using the first frequency band and transmitting image data using the second frequency band.

Systems and methods described herein employ an allocation and retention priority for user equipment (UE), referred to as a UE ARP. The UE ARP may be defined per network slice, such that a subscriber can have different priority in different slices. According to one implementation, a network device receives, from a UE device, a registration request requesting access to a network slice and obtains a UE ARP. The UE ARP associates the UE device with a priority level on the network slice. When the network device determines that a maximum number of terminals are using the network slice, it applies the priority level in the UE ARP to grant or deny the UE device access to the network slice.

Techniques described herein improve direct communication channel reliability in a vehicle-to-everything (V2X) communication. The techniques include a (wireless communication) device that uses a first licensed band to perform a cellular network communication through a first interface (e.g., Uu), and further uses a shared spectrum to perform a V2X communication through a direct communication channel interface. The device then monitors and compares a bandwidth requirement of the V2X communication with a bandwidth of the shared spectrum. In response to the bandwidth that is less than the bandwidth requirement, the device selects a second licensed band that includes a bandwidth that is at least equal to the bandwidth requirement. Further, the selected second licensed band is different from the first licensed band to avoid channel interference. In other embodiments, the device uses the licensed band to directly establish the V2X communication.

An apparatus and system to enable dynamic offloading and execution of compute tasks are described. In split CU-DU RAN architectures, the CU-CP is connected with multiple compute control functions (CF) and service functions (SF) that have different computing hardware/software capabilities. Different architectures depend on whether the SF is collocated with the CU-UP, the CU-UP and SF only serve compute messages, a compute message is supplied directly to the CU-UP or also traverses the CU-CP. In response to reception from a UE of a compute message containing data for computation being sent to the CU-CP through the DU, the CU-CP sends the data to the SF with identifiers and sends the result to the UE.

A transmit chain (TX chain) of a user equipment (UE) transmits an uplink signal to a first wireless network associated with a first base station or a second wireless network associated with a second base station. The uplink signal includes information indicative of a first receive chain (RX chain) of the UE being synchronized to the first base station to receive first traffic from the first wireless network, and a second RX chain of the UE being synchronized to the second base station to receive second traffic from the second wireless network. The UE transmits uplink traffic for the first wireless network and the second wireless network to the second base station via the TX chain of 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 computer-implemented system and method for automated traffic flow control using domain name for one or more devices enabled for connectivity over cellular network are disclosed. The computer-implemented method for automated traffic flow control using domain name for one or more devices enabled for connectivity includes receiving device information for the one or more devices; receiving domain name information for at least one domain name that the one or more devices are allowed to access, denied to access or a combination thereof; associating the at least one domain name with one or more internet protocol (IP) addresses; monitoring the at least one domain for change in the one or more IP addresses for that domain; and updating the one or more IP addresses of the domain name if any change in the one or more IP addresses for that domain is found.

The present invention relates to a receiver-centric transmission system for IoT systems, such as lighting networks, with combo protocol radio chips that share a single radio front-end for two or more transmission protocols of different network technologies while preventing unacceptable performance degradations in one or both protocol modes. The receiver-centric approach allows implementation of two networks with acceptable performances on one single radio chip per node rather than requiring two radio chips per node.

A system described herein may provide a technique for the differentiated Quality of Service (“QoS”) treatment of different traffic types associated with the same application (e.g., a “multi-persona” application) by a wireless network, without the exposure of an application identifier of the application to the wireless network. The application may provide a traffic type indication, based on which a User Equipment (“UE”) may establish one or more QoS flows or other types of communication sessions with the wireless network, where the QoS flows or other types of communication sessions are associated with a network slice that is associated with the traffic type. The communication sessions may include Data Radio Bearers (“DRBs”), backhaul links, protocol data unit (“PDU”) sessions, or other suitable types of communication sessions.