Embodiments of the present invention disclose a power control method and apparatus, where the method includes: performing a slow fading evaluation on an uplink channel of a UE to obtain a slow fading value of the uplink channel; comparing the slow fading value with a target slow fading value to obtain a first comparison result; generating, according to the first comparison result, first control signaling of a downlink control channel corresponding to the uplink channel, where the first control signaling is used to instruct the UE to adjust transmit power of the UE on the uplink channel; and sending the first control signaling to the user equipment UE. In the embodiments of the present invention, making full use of power efficiency, improving a cell throughput, and reducing neighboring cell interference.

A load balancing process includes determining when the cell is overloaded, determining whether the cell is in a hold state, maintaining a current mitigation state for the cell when the cell is determined to be in a hold state, determining whether traffic has decreased for the cell since a previous time and whether mitigation was applied to the cell at the previous time, applying a hold state to the cell when the traffic is determined to have decreased and the mitigation is determined to have been applied, determining whether performance has decreased by a predetermined level for the cell when the cell is not in the hold state, and applying mitigation to the cell when performance has decreased by at least the predetermined level. Such a process may be implemented as a state machine in a system.

A method and user equipment to select an emission power from a set of possible emission powers depending on their location relative to a base station. In a 5G development scenario, a massive number of user equipment will be deployed. The data exchanged by this user equipment is mainly signalling data whose volume generates an overload of the network resources. A resource access scheme called uncoordinated resource access scheme reduces the volume of the exchanged data. So that the base station can decode all signals emitted by the user equipment, it is necessary to have a number of emission power levels greater than the number of user equipment. By proposing the user equipment to select an emission power from a set of possible emission powers depending on their location relative to the base station, the solution allows the base station to decode the signals emitted by a greater number of user equipment.

A method for determining a power control parameter and a terminal. The method includes: in a case that no target parameter has been configured in power control parameters of a target object, determining a target parameter of the target object in any one of the following manners: determining, based on a target parameter of another object configured by a network device, the target parameter of the target object, where the another object is different from the target object; determining, based on a historical configuration, the target parameter of the target object; and determining, based on protocol specification, the target parameter of the target object; where the target object and the another object are selected from a physical uplink control channel PUCCH, a physical uplink shared channel PUSCH, and a sounding reference signal SRS.

An electronic device is provided. The electronic device includes a housing; a first antenna for transmitting and receiving at least one of a first wireless transmission signal and a first wireless reception signal using the first portion of the housing; a first PCB electrically connected to the first antenna and including a first connector; a second PCB electrically connected to the first PCB and including a second connector; a signal connection member having a first end connected to the first connector and a second end connected to the second connector; a communication module electrically connected to the second connector and controlling the at least one of the first wireless transmission signal and the first wireless reception signal; a sensor module which is electrically connected to the second connector, and adjusts at least one sensing parameter based on frequency information of the at least one of the first wireless transmission signal and the first wireless reception signal, and measures capacitance for a path of the at least one of the first wireless transmission signal and the first wireless reception signal between the first antenna and the second connector; and a processor configured to control the transmission power of the communication module according to the capacitance measured by using the sensor module.

Apparatuses, methods, and systems are disclosed for determining a maximum power reduction for non-contiguous radio resource allocations. One apparatus includes a processor that receives a non-contiguous resource allocation and calculates a fraction of resource block punctured from a smallest containing contiguous allocation (“SCCA”). Here, the SCCA is the smallest set of contiguous resource blocks that encompasses the non-contiguous resource allocation. The processor determines a first additional maximum power reduction for the non-contiguous resource allocation in response to the fraction of punctured resource blocks being less than a threshold value. The apparatus includes a transceiver that transmits an uplink signal on the non-contiguous resource allocation using the first additional maximum power reduction in response to the fraction of punctured resource blocks being less than the threshold value.

A wireless device includes a controller configured to identify a scheduled transmission including a first section having a first bandwidth and a second section having a second bandwidth, select a transmit power limit for the scheduled transmission based on a relative duration of the first section compared to the second section, and select a transmit power value based on the transmit power limit, and a transmitter configured to perform the scheduled transmission with a transmit power indicated by the transmit power value.

A method for suppressing a change of wireless power includes a parameter setting step, a first power verifying step, a power adjusting step and a second power verifying step. The parameter setting step is performed to set a power parameter set. The first power verifying step is performed to verify whether a first power difference is greater than the power adjustment start difference to generate a first verification result. The power adjusting step is performed to drive a processing unit to adjust the power amplifying unit according to the adjustment parameter set. The second power verifying step is performed to verify whether a second power difference is smaller than or equal to the power adjustment stop difference to generate a second verification result. The processing unit determines whether the power adjusting step is performed according to one of the first verification result and the second verification result.

A method for a terminal for transmitting a signal in a wireless communication system according to one embodiment of the present invention comprises: receiving repeated transmission related information comprising the count N by which an uplink signal transmission is to be repeated from a base station; determining the transmission power of the uplink signal; and transmitting repeatedly the uplink signal N times by the determined transmission power on the basis of the repeated transmission related information, wherein the terminal can determine the transmission power of the uplink signal on the basis of the count N by which the transmission of the uplink signal is to be repeated. The terminal is capable of communicating with at least one of another terminal, a terminal related to an autonomous driving vehicle, a base station or a network.

A communication device includes: a storing part storing a definition table where a reception power and a metric value are associated with each other, and a cumulative metric value; a receiving part that receives a broadcast signal transmitted from another communication device; a calculating part that acquires a metric value corresponding to a reception power of the broadcast signal received by the receiving part from the definition table, and calculates a cumulative metric value based on the acquired metric value and a metric value included in the received broadcast signal; and a determining part that updates a cumulative metric value stored in the storing part to the calculated cumulative metric value if the calculated cumulative metric value is smaller than the cumulative metric value stored in the storing part, and determines the other communication device transmitting the broadcast signal of the calculated cumulative metric value as a route construction target.