Abstract: A SmarterFi gateway integrates a WiFi access point and smart repeater, and executes a method therefor. The method includes receiving, from a user equipment (UE) via a first wireless communication channel, wireless fidelity (WiFi) signals that include information indicating a location of the UE. The WiFi signals are received by a transceiver that includes a first antenna array for communication with the UE, and a second antenna array for communication with a gNB. The method includes transmitting, to the gNB via the second antenna array, uplink data and control information that includes the UE location information. The method includes receiving, from the gNB via the second antenna array, downlink information intended for the UE. The method includes forward-transmitting, to the UE via a second wireless communication channel, the downlink information via a beam formed at the first antenna array to serve the UE at the location of the UE.

Abstract: A smart repeater includes a transceiver configured to receive a reference signal, receive, from a base station (BS), a subcarrier allocation for a plurality of user equipments (UEs), receive, from the BS, a downlink (DL) beam associated with the plurality of UEs, and retransmit the DL beam. The smart repeater further includes a processor, operatively coupled to the transceiver, the processor configured to determine a beam split configuration for the DL beam based on the subcarrier allocation, and cause the transceiver to retransmit the DL beam according to the beam split configuration. To retransmit the DL beam according to the beam split configuration the transceiver is further configured to generate a frequency dependent beam for each of the plurality of UEs, and direct the frequency dependent beam for each of the plurality of UEs to a UE associated with the frequency dependent beam.

Abstract: A method for positioning based system design for smart repeaters with adaptive beamforming capabilities is implemented by an electronic device. In certain embodiments, the electronic device is a smart repeater. The method includes obtaining user equipment (UE) location information indicating a location of a UE. The method includes translating, based on a prediction engine, the UE location information to a beam index associated with a beam to serve the UE at the location of the UE. The method includes receiving, from an external communication device via a first wireless communication channel, traffic intended for the UE. The method includes forward-transmitting, via a second wireless communication channel, the traffic via the beam formed at a transmit (TX) antenna of the electronic device.

Abstract: Configuration of a line of sight, multiple input, multiple output circular antenna array involves setting an integer number of antenna arrays up to a number of antenna ports for the circular antenna array and a maximum radius for any antenna ring within the circular antenna array. A capacity is determined for each of a plurality of different combinations of each of: an integer number of antenna rings up to a predetermined maximum number of antenna rings, a number of the antenna arrays for each of the number of antenna rings, and angular offsets for that antenna arrays on each of the antenna rings. The determined capacities for the plurality of different combinations are compared.

Abstract: A uniform circular array (UCA) is assisted with an analog inverse fast Fourier Fast transform (IFFT)/fast Fourier transform (FFT) precoder to reduce computational complexity in one or more line-of-sight (LoS) multiple-input multiple-output (MIMO) networks. Each port of the UCA includes a steerable miniaturized array with beam steering capability.

Abstract: A multi-layer reconfigurable reflective intelligent surface (RIS). The RIS includes a unit-cell of a reconfigurable intelligent surface. The unit-cell includes a first layer composed of a conductive material and structured according to a sub-wavelength reflective pattern. The first layer reflects an impinging wave at a predetermined phase and steers the reflected impinging wave toward an intended receiver. The unit-cell includes a second layer composed of a first dielectric substrate material. Between the first and second layers, the unit-cell includes a middle layer composed of a second dielectric material having tunable dielectric properties. Tuning a dielectric constant of the second dielectric material modifies the predetermined phase of reflection of the impinging wave.

Abstract: A method, implemented by a processor connected to a reconfigurable intelligent surface (RIS) system that includes one or more RISs, includes detecting one or more wireless control signals from a transmitter. The method includes identifying a channel state and one or more phases based on the detected wireless control signals; improving a beam-steering reflection matrix (?) of the RIS system based on a singular value decomposition of channel matrices; and configuring the RIS system based on the ?. Among the RISs, each RIS is configured to redirect an incident signal toward an antenna array of an intended receiver. The incident signal is received from the transmitter. Locations of the RIS and transmitter differ by a height placement value (hRIS). In a horizontal plane, the location of the RIS is a first distance (DTX-RIS) from the transmitter and a second distance (DRX-RIS) from the receiver.

Abstract: A system and method for an efficient port switching technique for line-of-sight multiple-input multiple-output communications by a base station is provided. The base station includes an antenna array comprising a first number of antenna ports. The base station also includes a transceiver configured to communicate in a wireless communication medium. The base station further includes a processor. The processor is configured to determine, based on the wireless communication medium, one or more parameters of the base station or a receive base station. The processor also is configured to select, based on the one or more first parameters and one or more second parameters, a second number of antenna ports to perform a communication with the receive base station.

Abstract: A multi-layer reconfigurable reflective intelligent surface (RIS). The RIS includes a unit-cell of a reconfigurable intelligent surface. The unit-cell includes a first layer composed of a conductive material and structured according to a sub-wavelength reflective pattern. The first layer reflects an impinging wave at a predetermined phase and steers the reflected impinging wave toward an intended receiver. The unit-cell includes a second layer composed of a first dielectric substrate material. Between the first and second layers, the unit-cell includes a middle layer composed of a second dielectric material having tunable dielectric properties. Tuning a dielectric constant of the second dielectric material modifies the predetermined phase of reflection of the impinging wave.