Aspects of the present disclosure relate to wireless communications, and more particularly, to techniques for handling maximum permissible exposure (MPE) events. In some cases, upon detecting an MPE event, a UE may provide assistance information that a base station may use to adjust uplink scheduling in an effort to reduce impact of the MPE event.

A method and apparatus are disclosed for utilizing UE beamforming in a wireless communication system. In one embodiment, the method includes the UE performing measurement to obtain a measurement result associated with a cell. The method also includes the UE determining whether to use the UE beamforming in the cell at least based on the measurement result, wherein the UE uses the UE beamforming in the cell if the measurement result is worse than a first threshold.

Aspects described herein relate to scheduling, or configuring a node to schedule, a transmission in multiple time periods based on a hopping pattern, where the hopping pattern includes at least one of a beam hopping pattern, a precoder hopping pattern, or a time hopping pattern. The transmission can be transmitted or received in the multiple time periods based on the hopping pattern.

Embodiments of the present application provide transmission control methods and transmission control apparatus. A method disclosed herein comprises: determining transmission capability of a first device; and determining transmission configuration between the first device and a second device at least according to the transmission capability of the first device, the transmission configuration comprising information associated with at least two multiple-input-multiple-output (MIMO) channels available for data transmission between the first device and the second device. The method and apparatus of the embodiments of the present application support that at least two separate MIMO channels coexist between an access terminal (AT) device and an access point (AP) device as well as between two AT devices, which have flexible configuration while ensuring a higher data transmission rate, and computational complexity is not high for the devices, which can reduce power consumption of the devices.

A mobile device includes a diversity antenna, a radio-frequency antenna, a first wireless communication circuit, a second wireless communication circuit and a first switching circuit. The second wireless communication circuit is electrically connected to the radio-frequency antenna. The first switching circuit is electrically connected to the diversity antenna, the first wireless communication circuit and the second wireless communication circuit. In a first mode, the diversity antenna is conducted to the first wireless communication circuit through the first switching circuit, and the first wireless communication circuit receives a wireless signal through the diversity antenna. In a second mode, the diversity antenna is conducted to the second wireless communication circuit through the first switching circuit, and the second wireless communication circuit executes a multi-input multi-output transmission through the diversity antenna and the radio-frequency antenna.

A wireless communication device includes a plurality of antennas, transmission circuits, reception circuits, and a plurality of connecting units that connect the transmission circuits and the reception circuits associated with the respective antennas, and a processor. The processor executes outputting, at timing allowed for signal transmission from the antennas, first calibration signals; calculating, by using the first calibration signals having passed through the transmission circuits, a first correction value that corrects a difference between the transmission characteristics of the transmission circuits; outputting, at the timing allowed for the signal transmission from the antennas, a second calibration signal; and calculating, by using the second calibration signal having passed through the reception circuits, a second correction value that corrects a difference between the transmission characteristics of the reception circuits.

An initiator device is provided with a generation circuit for supporting Single User (SU)-Multiple Input Multiple Output (MIMO) operation and generating a first signal including a value that indicates which of a reciprocal MIMO phase and a non-reciprocal MIMO phase is to be applied to SU-MIMO BF training, and a transmission circuit for transmitting the first signal to a responder device. The responder device is provided with a reception circuit for receiving the first signal from the initiator device, and a processing circuit for determining on the basis of the value which of the reciprocal MIMO phase and the non-reciprocal MIMO phase is to be applied to SU-MIMO BF training.

An apparatus includes multiple signal paths for signal transmission, and control circuitry. The multiple signal paths include a first signal path and a second signal path. The first signal path is configured to convert a digital baseband signal to a first radio frequency (RF) signal having a first frequency and a first gain. The second signal path is configured to convert a digital baseband signal to a second RF signal having a second frequency and a second gain, wherein the second gain is less than the first gain. The control circuitry is coupled to the plurality of signal paths and is configured to receive one or more control signals to enable selective activation of at least one signal path of the plurality of signal paths.

The present disclosure relates to correction apparatus and correction methods. One example correction apparatus includes a first adjustment module, a plurality of second adjustment modules, a correction calculation module, and a plurality of non-ideal channels. One second adjustment module is disposed on one non-ideal channel. The first adjustment module is connected to each non-ideal channel. The correction calculation module is separately connected to the first adjustment module and the plurality of second adjustment modules. The correction calculation module is connected to an output end of each non-ideal channel. The non-ideal channel is a channel that outputs an output signal in response to a drive signal having an error value.

The present disclosure relates to an electronic device, a method, and a storage medium for a wireless communication system. Various embodiments are described with respect to beam pair link. In one embodiment, the electronic device used at the base station side in the wireless communication system may comprise a processing circuitry configured to monitor status of an uplink signal; determine it necessary to adjust a first uplink beam pair link (BPL) based on the status of the uplink signal, wherein the first uplink BPL comprises a first transmitting beam at a terminal device side and a first receiving beam at the BS side; and perform operations in order to adjust the first uplink BPL.