Provided is a communication apparatus that flexibly switches execution/non-execution of FD. The communication apparatus includes the followings: a resource allocation unit that allocates, to another communication apparatus, reception radio resources in a predetermined frequency channel and allocates transmission radio resources at least partially overlapping the reception radio resources on a time axis; and a notification unit that notifies the other communication apparatus of information regarding the reception radio resources and the transmission radio resources. The resource allocation unit further allocates transmission radio resources at least partially overlapping the reception radio resources on a frequency axis.

Provided is a communication apparatus that flexibly switches execution/non-execution of FD. The communication apparatus includes the followings: a resource allocation unit that allocates, to another communication apparatus, reception radio resources in a predetermined frequency channel and allocates transmission radio resources at least partially overlapping the reception radio resources on a time axis; and a notification unit that notifies the other communication apparatus of information regarding the reception radio resources and the transmission radio resources. The resource allocation unit further allocates transmission radio resources at least partially overlapping the reception radio resources on a frequency axis.

The present disclosure selects a node generating a periodic time slot request in a network to construct a set of periodic time slot request generation nodes, and constructs a time slot request cycle set; selects a node generating an aperiodic time slot request in the network to construct a set of aperiodic time slot request generation nodes, and constructs a time set of the aperiodic time slot request generation nodes; calculates a time slot contention scheduling parameter of each node in the set of the periodic time slot request generation nodes; and if no aperiodic time slot request arrives, allocates a time slot to each time slot requesting node during periodic time slot scheduling; or if an aperiodic time slot request, namely, a sporadic time slot request, arrives, performs rescheduling through hybrid time slot scheduling based on arrival time of the aperiodic time slot request.

With advanced compute capabilities and growing convergence of wireless standards and artificial intelligence (AI) applications, there is a requirement to run multiple wireless standards, e.g., 4G LTE, 5G NR and Wi-Fi, and AI on a single hardware together. Typical solutions include reserving some compute resources for specific wireless standards and a dedicated AI resource due to different precision compared to baseband processing. Typical solutions for signal processing with converged wireless standards and machine learning (ML) applications include having dedicated hardware acceleration and reserving some commutating or processing resources for specific wireless standards and a dedicated AI operation. Such approaches result in inefficient use of resources and lack of operation flexibility. The present patent document discloses embodiments to leverage commonalities in hardware acceleration for converged baseband and AI operators, thus achieving improved efficiency in power consumption and improved hardware resources utilization.

With advanced compute capabilities and growing convergence of wireless standards and artificial intelligence (AI) applications, there is a requirement to run multiple wireless standards, e.g., 4G LTE, 5G NR and Wi-Fi, and AI on a single hardware together. Typical solutions include reserving some compute resources for specific wireless standards and a dedicated AI resource due to different precision compared to baseband processing. Typical solutions for signal processing with converged wireless standards and machine learning (ML) applications include having dedicated hardware acceleration and reserving some commutating or processing resources for specific wireless standards and a dedicated AI operation. Such approaches result in inefficient use of resources and lack of operation flexibility. The present patent document discloses embodiments to leverage commonalities in hardware acceleration for converged baseband and AI operators, thus achieving improved efficiency in power consumption and improved hardware resources utilization.

A terminal is provided. The terminal includes a communication unit configured to perform communication, and a control unit configured to request a service with priority control related to the communication. The control unit is: an application that performs configuration related to a resource control unit for distributing communication packets associated with a communication path; or a client of the service with priority control related to the communication.

A terminal is provided. The terminal includes a communication unit configured to perform communication, and a control unit configured to request a service with priority control related to the communication. The control unit is: an application that performs configuration related to a resource control unit for distributing communication packets associated with a communication path; or a client of the service with priority control related to the communication.

Proposed are a method and a device for obtaining critical update information between MLDs in a wireless LAN system. Specifically, a reception MLD transmits a probe request frame to a transmission MLD through a first link. The reception MLD receives a probe response frame from the transmission MLD through the first link. The transmission MLD comprises a first transmission STA operating in the first link and a second transmission STA operating in a second link. The probe request frame comprises a change sequence element which requests critical update information of the second transmission STA. The probe response frame comprises the critical update information of the second transmission STA.

A network slice switching method, a terminal, a storage medium and an electronic device, the method including steps that under the situation that a second terminal has established a connection with a first terminal, the second terminal displays a network slice list, where the network slice list includes a plurality of first network slices, and the first network slices provide a network data service for the second terminal; the second terminal receives a selection instruction; and the second terminal sends a target identifier of the target network slice to the first terminal so that the first terminal can switch the current network slice into the target network slice.

In an aspect, the present disclosure includes a method, apparatus, and computer readable medium for wireless communications for receiving, by a network entity from a user equipment (UE), a measurement report, wherein the network entity corresponds to a serving network entity; and determining, by the network entity, a single frequency network (SFN) network entity group for the UE based on the measurement report, wherein the SFN network entity group corresponds to a one or more neighbor network entities designated for transmitting SFN data to the UE.