Various aspects of the present disclosure generally relate to wireless communication. In some aspects, an apparatus of a user equipment (UE) may transmit a power headroom (PHR) parameter. The PHR parameter may be based at least in part on a beam being associated with a grating lobe and a main lobe. A power of the grating lobe may be within a power threshold of a power of the main lobe. The apparatus may perform a communication using the beam based at least in part on the PHR parameter. Numerous other aspects are described.

Methods, systems, and devices for wireless communications are described. Generally, the described techniques provide for a first transmission from a first device to be received at a second device. The second device may determine one or more interference parameters (e.g., a maximum allowable interference power) for receiving the first transmission from the first device, and the second device may transmit an indication of the one or more interference parameters using a full-duplex operation (e.g., using resources overlapping with resources used to receive the first transmission). The third device may receive the indication of the one or more interference parameters and determine transmission parameters (e.g., a maximum transmit power) for communicating with a fourth device based on the one or more interference parameters. The third device may transmit a second transmission to the fourth device based on the transmission parameters.

A data processing method includes initiating, to a cloud server, a first message used to access a roadside device or used to obtain signal transmit power-related information of static roadside equipment, receiving a second message fed back by the cloud server, where the second message is determined by the cloud server based on the first message and a prestored high-definition map, and the second message includes related information about accessing the roadside device by the vehicle-end device, or the signal transmit power-related information of the static roadside equipment, and accessing the roadside device based on the second message or determining a signal transmit power of the vehicle-end device based on the second message.

A method includes simulating, using processing circuitry, one or more sector antenna transmitting at a selected transmission power, each of the one or more sector antenna simulated as being located at a desired physical location. The method also includes determining, based on results of the simulation, a short-term interference and a long-term interference for each of the one or more sector antenna. The method also includes performing, by the processing circuitry and based on a short-term interference threshold and a long-term interference threshold for the one or more sector antenna, one or more of: increasing the selected transmission power for one of the one or more sector antenna, decreasing the selected transmission power for the one of the one or more sector antenna, or maintaining the selected transmission power for the one of the one or more sector antenna.

The present invention provides a method of determining a transmission power for device to device, D2D, transmissions between a first user equipment device and a second user equipment device using transmission resources being used for transmissions to a cellular network entity by a third user equipment device, the method comprising determining a measure of a path loss between the cellular network entity and the first user equipment device, and using the measure of the path loss to determine a maximum transmission power such that the D2D transmissions are received at the cellular network entity with a signal level around or below a noise level.

The described technology is generally directed towards accelerating distributed principal components in the presence of noisy channels. A federated training based method is disclosed. The method can calculate a desired common subspace for edge devices under the coordination of a server. The server can be connected to the edge devices via noisy wireless channels. A broadband communication system can be used, wherein devices can transmit local gradients by linear analog modulation over sub-channels in communication rounds for over-the-air aggregation. Before each communication round, the server can detect information of a current region. Based on the region information, an online region-adaptive power control scheme can be applied to accelerate the process.

A method for operation of a first device (100) in a wireless communication system is proposed. The method can comprise the steps of: determining a transmission parameter relating to a sidelink positioning reference signal (S-PRS) on the basis of information obtained by means of the first device (100); and transmitting the S-PRS on the basis of the transmission parameter.

An information processing device (60) includes: an acquisition unit (641) that acquires information regarding each of a plurality of second radio systems that share a radio wave used by a first radio system; a calculation unit (642) that calculates an allocation priority for each of the plurality of second radio systems based on the information acquired by the acquisition unit (641); and an allocation unit (643) that allocates, as an interference amount, a total interference amount allowed by the first radio system to each of the plurality of second radio systems based on the allocation priority calculated by the calculation unit (642).

Communication management hardware controls operation of multiple wireless stations in a network environment. For example, the communication management hardware initially assigns wireless bandwidth for use by multiple wireless stations in a wireless network environment to communicate amongst each other. The communication management hardware monitors use of the wireless bandwidth. In response to detecting use of the wireless bandwidth by an incumbent entity having higher priority rights than the multiple wireless stations, the communication management hardware operates in a shared time-division mode in which both the multiple wireless stations and the incumbent entity share use of the wireless bandwidth in a control period according to a duty cycle in which the wireless stations are provided full use of the wireless bandwidth during a first portion of the control period and the wireless stations are provided reduced use of the wireless channels for a second portion of the control period.

There is provided an apparatus that acquires information indicating a result of detection of a communication node managed by a second frequency usage control system and notifies the second frequency usage control system of first sharable information generated from first frequency usage information related to a first communication node managed by a first frequency usage control system. The first sharable information being held by a first database included in the first frequency usage control system.