The present invention relates to a device for sharing the antennas of wireless access node systems in a wireless communication network comprising a wireless access node system A and a wireless access node system B, each of which comprises at least one transmission/reception unit for processing transmission/reception signals in at least one frequency band, the device comprising: an MIMO coupler A for coupling a signal in a first transmission/reception route among multiple input multiple output (MIMO) routes for said at least one transmission/reception unit of the wireless access node system A, and a signal in a second transmission/reception route among MIMO routes for said at least one transmission/reception unit of the wireless access node system B, to the antenna of the wireless access node system A; and an MIMO coupler B for coupling a signal in a first transmission/reception route among the MIMO routes for said at least one transmission/reception unit of the wireless access node system B, and a signal in a second transmission/reception route among the MIMO routes for said at least one transmission/reception unit of the wireless access node system A, to the antenna of the wireless access node system B.

Embodiments of the present invention provide a signal transmission method and device. The method includes determining, by a first device, uplink transmit power and sending, by the first device on a first time-frequency resource by using the uplink transmit power, an uplink signal to a second device that operates in a full-duplex mode, where the uplink transmit power is power determined according to a self-interference compensation amount of the second device, or the uplink transmit power is maximum transmit power of the first device.

Embodiments of the present invention provide a signal transmission method and device. The method includes determining, by a first device, uplink transmit power and sending, by the first device on a first time-frequency resource by using the uplink transmit power, an uplink signal to a second device that operates in a full-duplex mode, where the uplink transmit power is power determined according to a self-interference compensation amount of the second device, or the uplink transmit power is maximum transmit power of the first device.

Examples disclosed herein relate to a communication system including a transceiver module, a rearrangeable switch network coupled to the transceiver module, a power distribution network coupled to the rearrangeable switch network, and a plurality of Beam Steering Phase Array (“BSPA”) antennas, each coupled to the power distribution network and dynamically controllable to generate beams according to a power regulation requirement for a set of satellites.

Examples disclosed herein relate to a communication system including a transceiver module, a rearrangeable switch network coupled to the transceiver module, a power distribution network coupled to the rearrangeable switch network, and a plurality of Beam Steering Phase Array (“BSPA”) antennas, each coupled to the power distribution network and dynamically controllable to generate beams according to a power regulation requirement for a set of satellites.

A method includes transmitting a training signal derived from a sequence, the training signal facilitates an estimation of a channel impulse response (CIR) for a communications channel between a transmit antenna of the device and a receive antenna of the device, estimating the CIR for the communications channel, and receiving signals corresponding to a first transmission at the receive antenna. The method also includes cancelling self-interference present in the received signals in accordance with the estimated CIR, the self-interference arising from a second transmission made by the transmit antenna of the device, thereby producing an interference canceled received signal, and processing the interference canceled received signal.

Embodiments of the present disclosure provide methods, devices and computer readable media for communication. In a method implemented at a network device, the method comprising allocating, at a network device, available resource block groups RBGs to a plurality of terminal devices; determining the number of shared RBGs in the available RBGs, the shared RBGs being shared by the plurality of terminal devices; determining a sum of shared number of the shared RBGs per each of the plurality of terminal devices; determining an average value of the transmit power base on the number of available RBGs and a total power of the network device, the average value indicating a basic power allocated by the network device to the plurality of terminal devices; determining an offset value of a transmit power for each of the plurality of terminal devices based on the number of shared RBGs, the sum of the shared number and the average value; and determining a target value of the transmit power for each of the plurality of terminal devices based on the offset value and the average value.

Embodiments of the present disclosure provide methods, devices and computer readable media for communication. In a method implemented at a network device, the method comprising allocating, at a network device, available resource block groups RBGs to a plurality of terminal devices; determining the number of shared RBGs in the available RBGs, the shared RBGs being shared by the plurality of terminal devices; determining a sum of shared number of the shared RBGs per each of the plurality of terminal devices; determining an average value of the transmit power base on the number of available RBGs and a total power of the network device, the average value indicating a basic power allocated by the network device to the plurality of terminal devices; determining an offset value of a transmit power for each of the plurality of terminal devices based on the number of shared RBGs, the sum of the shared number and the average value; and determining a target value of the transmit power for each of the plurality of terminal devices based on the offset value and the average value.

A communication device includes one or more processors, configured to receive data representing each of at least a first waveform and a second waveform from a common control channel and data representing a third waveform from a data channel associated with the control channel; determine from the received data, channel state information for each of the first waveform and the second waveform; determine a Doppler shift between the channel state information for the first waveform and the channel state information for the second waveform; compare the determined Doppler shift to a predetermined Doppler shift threshold; and if the determined Doppler shift is less than the predetermined Doppler shift threshold, adjust the third received waveform by the determined Doppler shift and decode the adjusted third received waveform.

A communication device includes one or more processors, configured to receive data representing each of at least a first waveform and a second waveform from a common control channel and data representing a third waveform from a data channel associated with the control channel; determine from the received data, channel state information for each of the first waveform and the second waveform; determine a Doppler shift between the channel state information for the first waveform and the channel state information for the second waveform; compare the determined Doppler shift to a predetermined Doppler shift threshold; and if the determined Doppler shift is less than the predetermined Doppler shift threshold, adjust the third received waveform by the determined Doppler shift and decode the adjusted third received waveform.