A multi-mode wireless terminal, which includes a path of a first wireless communications standard and a path of a second wireless communications standard; the path of the first wireless communications standard includes a first antenna module, a first transceiver module and a first baseband module, where the first antenna module connects to the first transceiver module, and the first transceiver module connects to the first baseband module; the path of the second wireless communications standard includes a second antenna module, a second transceiver module and a second baseband module, where the second antenna module connects to the second transceiver module, and the second transceiver module connects to the second baseband module; the second transceiver module connects to the first baseband module; the second antenna module and the second transceiver module serve as a diversity receive path of the first wireless communications standard when at an idle timeslot.

Provided is a frame configuration usable for both SISO transmission and MISO and/or MIMO transmission. A frame configurator of a transmission device configures a frame by gathering data for SISO and configures a frame by gathering data for MISO and/or MIMO data, thereby to improve the reception performance (detection performance) of a reception device.

A communication device configured to operate in a Multiple-input Multiple-output (MIMO) operation mode and Single-input Single output (SISO) operation mode and operation mode switching method are described. The communication device can include a transceiver associated with a first antenna, and configured to wirelessly communicate via the first antenna using a first communication technology; a second antenna associated with a second communication technology different from the first communication technology; and a controller coupled to the transceiver. The controller can be configured to: determine communication information corresponding to the first and the second communication technologies; and control the communication device to switch an operation mode of the communication device between the MIMO operation mode and the SISO operation mode based on the determined communication information.

The present invention relates to a system for providing distributed communication between communication terminals and a method for same. The method for providing distributed communication between communication terminals in a communication system includes the steps of: a first communication terminal receiving at least one first signal from at least one target communication device; the first communication terminal collecting at least one second signal that at least one second communication terminal receives from the at least one target communication device and at least one third signal that the at least one second communication terminal obtains by processing the at least one second signal in a preset processing scheme; and the first communication terminal combining the at least one first signal and the at least one second signal, or the at least one first signal and the at least one third signal.

Systems, methods, and other embodiments associated with a hybrid beamforming architecture are described. According to one embodiment, an apparatus comprises a beamforming architecture including a baseband unit and a processor. The beamforming architecture is configured to determine a steering matrix based on at least the baseband unit and the processor; and wherein the beamforming architecture is configured to simultaneously support a plurality of beamformee client devices, each beamformee client device beamformed by a beamformer with at least one of a beamformer hardware mode and a beamformer software mode and with at least one of a beamformer explicit mode and a beamformer implicit mode.

Provided is a frame configuration usable for both SISO transmission and MISO and/or MIMO transmission. A frame configurator of a transmission device configures a frame by gathering data for SISO and configures a frame by gathering data for MISO and/or MIMO data, thereby to improve the reception performance (detection performance) of a reception device.

Devices, systems, and methods are presented for a wireless base station to assign dynamically a plurality of radio transceiver chains among a varying number of wireless channels. In this manner, the communication system including the wireless base station may transition between a range extension mode and an enhanced capacity mode. In the range extension mode, a system is configured for maximum communication range with Subscriber Stations that are relatively distant from the radio transceiver chains, although communication is still possible with nearby Subscriber Stations. In the enhanced capacity mode, the system is configured for maximum communication throughput with Subscriber Stations that are relatively near to the radio transceiver chains, whereas communication with relatively distant Subscriber Stations will be either terminated or at least non-optimized.

Certain aspects of the present disclosure relate to switching mode of operation between an apparatus and a wireless node. An apparatus for wireless communication may generate a first frame comprising one or more fields indicating at least one of a request to change a mode for communication between the apparatus and a wireless node, wherein the change in the mode includes switching to one of single-input single-output (SISO), single-user multi-input multi-output (SU-MIMO), or multi-user MIMO (MU-MIMO) operation, or one or more parameters related to the change and output the first frame for transmission. Correspondingly, an apparatus for wireless communication may obtain a first frame comprising one or more fields indicating a request to change a mode for communication between the apparatus and a wireless node or parameters related to the change and take one or more actions to communicate in accordance with the change in the mode or the parameters.

An antenna device including: a first antenna assembly configured to receive first radiofrequency signals polarized according to a first polarization; a second antenna assembly configured to receive second radiofrequency signals polarized according to a second polarization orthogonal to the first polarization; and a radiofrequency signal handling assembly coupled with the first and second antenna assemblies, and configured to handle the received first radiofrequency signals separately from the received second radiofrequency signals.

A radio signal processing system includes a first antenna; a second antenna; a first receiver communicatively coupled to the first antenna; a second receiver communicatively coupled to the second antenna; a first processing unit communicatively coupled to the first receiver and configured to receive a first signal from at least one of the first antenna and the second antenna when the system is operating in a first mode; a second processing unit communicatively coupled to the second receiver and configured to receive a second signal from the second antenna when the system is operating in a first mode; and wherein the first processing unit is further configured to receive a third signal from both the first antenna and the second antenna when the system is operating in a second mode.