Abstract: Technology for a channelization device of a wideband repeater is disclosed. The channelization device can include a first diplexer and a second diplexer. The channelization device can include a plurality of switchable signal paths between the first diplexer and the second diplexer operable to perform channelized passive filtering of signals in defined bands. The channelization device can include a plurality of switchable pass through signal paths between the first diplexer and the second diplexer operable to pass through signals in the defined bands without filtering of the signals. The channelization device can be configured to perform channelized passive filtering of signals with no amplification of the signals.

Abstract: Technology for a repeater is disclosed. The repeater can include a first-direction signal path, a second-direction signal path and a controller. The controller can set a first gain for the first-direction signal path based on a second-direction received signal level. The controller can set a second gain for the second-direction signal path based on the second-direction received signal level with a differential with respect to the first gain. The differential between the first gain and the second gain can be set for a first signal type. The controller can adjust the differential between the first gain and the second gain for a second signal type.

Abstract: Technology for a repeater is disclosed. The repeater can include a first-direction signal path for a first-direction band. The repeater can include a second-direction signal path for a second-direction band. The repeater can include a controller configured to decrease a gain of the first-direction signal path by a first amount. The controller can increase a gain of the second-direction signal path by a second amount when the gain of the first-direction signal path is decreased by the first amount to enable a total loop gain of the first-direction signal path and the second-direction signal path to be less than a total loop crossover isolation level of the first-direction signal path and the second-direction signal path.

Abstract: Technology for a desktop signal booster is disclosed. The desktop signal booster can include a cellular signal amplifier, an integrated device antenna coupled to the cellular signal amplifier, an integrated node antenna coupled to the cellular signal amplifier, and wireless charging circuitry. The cellular signal amplifier can be configured to amplify signals for a wireless device, and the wireless device can be within a selected distance from the desktop signal booster. The integrated device antenna can be configured to transmit signals from the cellular signal amplifier to the wireless device. The integrated node antenna can be configured to transmit signals from the cellular signal amplifier to a base station. The wireless charging circuitry can be configured to wirelessly charge the wireless device when the wireless device is placed in proximity to the desktop signal booster.

Abstract: Technology for a signal booster is disclosed. The signal booster can identify a current location of the signal booster. The signal booster can determine one or more bands in which signals are permitted to be boosted by the signal booster based on the current location of the signal booster. The signal booster can boost signals in the one or more bands that are permitted to be boosted by the signal booster for the current location of the signal booster.

Abstract: Technology for a cellular signal booster operable to amplify cellular signals is disclosed. The cellular signal booster can include a downlink cellular signal path configured to amplify and filter a received downlink cellular signal in a plurality of selected bands. The downlink signal path can combine at least a first band and a second band in the plurality of selected bands. The cellular signal booster can include a controller operable to perform network protection by adjusting an uplink gain or noise power for at least one of a first band or a second band in an uplink signal path. The uplink gain or noise power can be adjusted for the first band in the uplink signal path or the second band in the uplink signal path using a signal strength associated with the received downlink cellular signal on the downlink cellular signal path.

Abstract: Technology for a cellular signal booster with a satellite location system signal rebroadcast functionality is disclosed. The cellular signal booster can identify a satellite location system signal received via a satellite location system module of the cellular signal booster. The cellular signal booster can provide the satellite location system signal to a signal path for amplification of the satellite location system signal. The cellular signal booster can broadcast an amplified satellite location system signal to a mobile device within a defined distance from the cellular signal booster.

Abstract: Technology for a multi-repeater system including wireless transmission of power from a first repeater to a second repeater is disclosed. A first and second repeater can be disposed opposite each other about a structural element. Wireless power can be transmitted from the first repeater through the structural element to the second repeater for use by the second repeater.

Abstract: A technology is described for a signal booster. The signal booster can include a selected number of uplink transmission paths. Each uplink transmission path can be configured to amplify an uplink signal on a selected band. The signal booster can include a selected number of downlink transmission paths. Each downlink transmission path can be configured to amplify a downlink signal on a selected band. One or more of the selected number of uplink transmission paths or the selected number of downlink transmission paths can include multiple parallel signal paths that are redundant for a same selected band, respectively.

Abstract: Technology for a multi-port repeater is disclosed. The multi-port repeater can include a plurality of ports. The multi-port repeater can include one or more amplifiers coupled to the plurality of ports. The multi-port repeater can determine one or more active ports from the plurality of ports. The multi-port repeater can determine an allocation of transmit power or gain between the one or more active ports up to a composite transmit power or gain. The multi-port repeater can adjust an output power or gain of each of the one or more amplifiers based on the allocation of the transmit power or gain between the one or more active ports.

Abstract: Technology for a signal booster is disclosed. The signal booster can include a first triplexer. The signal booster can include a second triplexer. The signal booster can include a first direction signal path communicatively coupled between the first triplexer and the second triplexer. The first direction signal path can be configured to amplify and filter first direction signals in one or more first direction bands, and the one or more first direction bands can be spectrally adjacent bands. The second direction signal path can be configured to amplify and filter second direction signals in one or more second direction bands, and the one or more second direction bands can be spectrally adjacent bands.

Abstract: A repeater system including one or more donor antennas, one or more server antennas and a repeater integrated with a pole.

Abstract: Technology for a repeater is disclosed. The repeater can include a power amplifier and a controller. The controller can determine whether a load is connected to the repeater. The controller can protect the power amplifier when the load is not connected to the repeater by disabling the power amplifier. The controller can unprotect the power amplifier when the load is connected to the repeater by enabling the power amplifier.

Abstract: Technology for a repeater configured to perform variable bandwidth filtering of signals is disclosed. The repeater can include a signal path for a radio frequency (RF) signal. The signal path can include a fixed-bandwidth low pass filter (LPF) operable to perform a variable bandwidth filtering of the RF signal to produce a channelized signal. The variable bandwidth filtering at the LPF can be performed by adjusting a first variable local oscillator (LO). The signal path can include a fixed-bandwidth high pass filter (HPF) operable to perform a variable bandwidth filtering of a channelized signal output from the LPF. The variable bandwidth filtering at the HPF can be performed by adjusting a second variable LO. The first variable LO and the second variable LO can be set to create a variable bandwidth that enables the repeater to perform variable bandwidth filtering of the signals.

Abstract: Technology for a repeater is disclosed. The repeater can include a first coaxial cable with a first defined connection. The repeater can include a repeater unit communicatively coupled to the first coaxial cable via the first defined connection. The repeater can include a controller configured to adjust a gain or output power of the repeater unit that accounts for known losses on the first coaxial cable.

Abstract: Technology for a repeater is disclosed. The repeater can include a first defined connection. The repeater can include a first coaxial cable connector configured to be communicatively coupled to the first defined connection. The repeater can include a repeater unit communicatively coupled to the first defined connection. The repeater can include a controller configured to adjust a gain or output power of the repeater unit that compensates for insertion losses between the first coaxial cable connector and the first defined connection.