A technology is described for adjusting repeater gain based on user equipment need. A downlink path of the repeater can be deactivated. A deactivated throughput value can be received from the UE for data received at the UE in a selected time period. The downlink amplification path of the repeater can be activated. An activated throughput value for data received at the UE in the selected time period can be received from the UE. A difference can be determined between the deactivated throughput value and the activated throughput value. A repeater gain value can be reduced or bypassed when the deactivated throughput value is greater than the activated throughput value by a selected threshold value.

Examples disclosed herein relate to a dual-relay antenna system that includes a first passive reflect array configured to receive electromagnetic radiation from a transmitting source and generate a transmit beamforming signal with a first gain from the electromagnetic radiation. The high gain relay antenna system also includes a second passive reflect array positioned at a predetermined distance from the first passive reflect array and configured to collimate phases of the transmit beamforming signal from the first passive reflect array and transmit an outbound beamforming signal with a second gain greater than the first gain, to a coverage area. Other examples disclosed herein relate to a dual-reflect array system and a method of high gain relay with multiple passive reflect array antennas.

Radio frequency signal boosters serving as outdoor cellular infrastructure are provided. In certain embodiments, a signal booster system for a high frequency cellular network includes a parabolic base station antenna configured to receive a downlink signal of a frequency band higher than 20 gigahertz and to transmit an amplified uplink signal of the frequency band, booster circuitry configured to amplify an uplink signal to generate the amplified uplink signal and to amplify the downlink signal to generate an amplified downlink signal, and a mobile station antenna configured to receive the uplink signal and to transmit the amplified downlink signal.

A technology is described for a repeater. The repeater can be configured to: receive an access level indicator from a spectrum access system (SAS) for a selected contested frequency band; identify one or more sub-bands available to the repeater in the selected contested frequency band based on the access level indicator; and activate the repeater for the one or more sub-bands when the access level permits repeater access.

An improved amplification of multiband signals for an uplink, in particular a satellite uplink is provided. For this purpose, multiple signals for separate frequency bands may be provided to a number of two or more uplink converters. The output of each uplink converter is amplified by a separate amplifier and the separately amplified signals are combined to obtain an amplified multiband uplink signal. In particular a waveguide combiner may be used for combining the amplified signals.

Techniques are disclosed for implementing am Intelligent Distributed Relay (IDR). The IDR may advantageously use the best qualities of both amplify-and-forward and decode-and-forward solutions. The advantageously leverages the use of a digital signal processing (DSP) circuitry, which may decode the data and control information. The control information may be used to control IDR behavior (e.g., in the uplink and/or downlink directions) and to enhance its characteristics.

An integrated repeater system that includes a repeater device having phased array antenna receivers that receives a mmWave radio frequency signal from a base station, and one or more phased array antenna transmitters that transmits the received mmWave radio frequency signal through a glass structure to a user equipment with a first level of transmission loss. Based on an impedance matching component provided in the integrated repeater system, the repeater device changes a filter response of the glass structure based on a dielectric property of the impedance matching component.

Technology for a repeater is disclosed. The repeater can include a first port, a second port, and a third port. The repeater can include a first amplification and filtering path communicatively coupled between the first port and the second port for a first frequency range. The repeater can include a second amplification and filtering path communicatively coupled between the first port and the third port for a second frequency range. The first frequency range can be spectrally adjacent to the second frequency range in a same signal direction, and a combination of the first frequency range and the second frequency range can have a fractional bandwidth that is greater than a defined fractional bandwidth threshold ratio for a selected filter type.

Techniques are disclosed for implementing am Intelligent Distributed Relay (IDR). The IDR may advantageously use the best qualities of both amplify-and-forward and decode-and-forward solutions. The advantageously leverages the use of a digital signal processing (DSP) circuitry, which may decode the data and control information. The control information may be used to control IDR behavior (e.g., in the uplink and/or downlink directions) and to enhance its characteristics.

A method is disclosed for estimating one or more user terminal locations over a target coverage area by wireless signals transmitted by one or more access points and reflected by one or more reconfigurable intelligent surface panels. The method includes transmission of one or more pilot signals by each of the one or more access points, reflecting, by at least one of the one or more reconfigurable intelligent surface panels, the one or more pilot signals according to one or more predetermined reflection patterns, receiving the reflections by the user terminal, extracting one or more features from the reflections, and estimating of a user terminal location by a method based on a database comprising pairs of locations and the one or more features.