A power adjustment method and an electronic device are provided. The method includes: detecting whether first information meets a first preset condition, where the first information includes at least one of the following: a first retransmission rate for uplink data, an actual transmission power for uplink data, or a first maximum transmission rate for uplink data, where the first maximum transmission power is a power threshold for transmitting the uplink data configured by a network device for the electronic device; and in a case that the first information meets the first preset condition, using a preset power control algorithm to adjust the first maximum transmission power to a target transmission power, where the target transmission power is greater than the first maximum transmission power and less than or equal to an inherent maximum transmission power of a radio frequency device of the electronic device.

Disclosed is a user equipment for satellite communication, comprising one or more processing circuits configured to execute the following operations: evaluating a transmission power requirement for a user equipment to communicate with a satellite; and assisting, via an auxiliary device, the user equipment in executing at least part of the communication with the satellite when the transmission power constraint of the user equipment fails to meet the transmission power requirement, wherein the processing circuits are further configured to acquire, via the satellite, a communication mode to be switched to, and the processing circuits transmit, to the satellite, a notification indicating that a current communication mode needs to be switched, with the notification comprising information indicating the need to switch to a communication mode that meets the transmission power requirement.

Embodiments provide a user equipment for a wireless communication system. The user equipment is configured to communicate with at least one other user equipment of the wireless communication system using a sidelink resource pool of the wireless communication system. Further, the user equipment is configured to transmit, responsive to an external emergency situation, an emergency notification signal on a resource of the wireless communication system. Thereby, the user equipment is configured to transmit the emergency notification signal with a transmit power that is greater than a regular transmit power used by the user equipment for transmitting regular signals.

Methods and apparatuses are disclosed for configuring full power transmission modes in a UE. The disclosed full power transmission modes include a Mode 0 and a Mode 3, which are enhancements over previous modes disclosed in the 3GPP specification. The UE gathers supported modes and configuration capabilities, such as number of ports and supported coherency schemes, and forwards the configuration capabilities to the network. The network analyzes the received information and selects a supported full power transmission mode based on the UE capabilities. The selection is then transmitted to the UE in a PUSCH-Config message. The UE extracts the selection from the PUSCH-Config message, and configures its radio accordingly.

A. terminal according to an aspect of the present disclosure includes a control section that determines whether or not to perform uplink shared channel transmission for an antenna. selection TPMI precoder at full power on the basis of a reported full power transmission mode to be supported and a reported transmitted preceding matrix indicator (TPMI) group, and a transmitting section that performs the uplink shared channel transmission using the antenna selection. TPMT. precoder. According to one aspect of the present disclosure, it is possible to control full power transmission appropriately.

Disclosed are techniques for wireless sensing. In an aspect, a user equipment (UE) detects an object and a direction to the object in an environment of the UE, determines whether the object is a human, identifies, based on the object being the human, a sensitive body part of the human, and performs, based on identification of the sensitive body part, a maximum power exposure (MPE) mitigation operation.

An information handling system of a management and orchestration module (MANO) may comprise a processor configured to determine user equipment device (UE) connectivity requirements for multiple UEs managed by the MANO, including a first UE transceiving via a first secure wireless link and a Wireless Local Area Network (WLAN) antenna with a non-cellular Access Point (AP), determine enterprise profile requirements for the UEs and detected network conditions of radio access networks (RANs) and cores of an enterprise mobile network, generate an optimal wireless link distribution across UEs that prioritizes access for the first UE to links with RANs, and determine a wireless link configuration adjustment for the first UE instructing termination of the first secure wireless link and establishment of a second secure wireless link with a RAN, according to the optimal wireless link distribution. A network interface device may transmit the wireless link configuration adjustment to the first UE.

An electronic device is provided. The electronic device includes a transceiver module supporting at least one communication method and a processor operatively connected to the transceiver module. The processor may identify an output state of a signal corresponding to the at least one communication method through the transceiver module, may detect a signal output level corresponding to the at least one communication method of the signal being output, may identify use pattern information corresponding to the at least one communication method through the transceiver module, and may adjust a transmission power value corresponding to the at least one communication method based on the detected signal output level and the use pattern information.

Aspects of the present disclosure relate to wireless communications, and more particularly, to techniques for managing uplink power control. For example, the techniques may be used for uplink power control for physical uplink shared channel (PUSCH) transmissions from unmanned aerial vehicles (UAVs).

A first radio access network, RAN, node in a communication network can determine whether to provide dual connectivity to a user equipment, UE, in the communication network based on an UL quality. The first RAN node can receive data indicating characteristics of an uplink, UL, channel of one or more UL channels for a second RAN node in the communication network. The first RAN node can estimate an UL quality of the UL channel based on the data. The first RAN node can determine based on the UL quality, whether to provide dual connectivity to the UE in the communication network by adding the second RAN node as a secondary node serving the UE.