Abstract: Systems and methods are provided for redundant antenna systems and methods of managing the power allocated thereto. A redundant antenna system comprises a first antenna array and a second antenna array, wherein each of the first and second antenna arrays are oriented to transmit downlink signals to different geographic areas. A first set of antenna elements of the first antenna array and a second set of antenna elements of the second antenna array are powered by a common power supply. In a normal operating mode, the power supply only powers the first set of antenna elements and in aspects of a redundant operating mode used to serve a degraded geographic service area, the power supply powers both the first set of antenna elements and the second set of antenna elements.

Abstract: Methods and systems are provided for dynamically assigning a wireless communication protocol to one or more antenna elements of an antenna array. The methods can include receiving information associated with one or more user devices and, based on the received information, identifying one or more antenna elements of the antenna array, for switching between first and second wireless communication protocols. The methods can also include switching the one or more antenna elements between the first and second wireless communication protocols.

Abstract: Systems and methods are provided for redundant antenna systems and methods of managing the power allocated thereto. A redundant antenna system comprises a first antenna array and a second antenna array, wherein each of the first and second antenna arrays are oriented to transmit downlink signals to different geographic areas. A first set of antenna elements of the first antenna array and a second set of antenna elements of the second antenna array are powered by a common power supply. In a normal operating mode, the power supply only powers the first set of antenna elements and in aspects of a redundant operating mode used to serve a degraded geographic service area, the power supply powers both the first set of antenna elements and the second set of antenna elements.

Abstract: Systems and methods are provided for redundant antenna systems and methods of managing the power allocated thereto. A redundant antenna system comprises a first antenna array and a second antenna array, wherein each of the first and second antenna arrays are oriented to transmit downlink signals to different geographic areas. A first set of antenna elements of the first antenna array and a second set of antenna elements of the second antenna array are powered by a common power supply. In a normal operating mode, the power supply only powers the first set of antenna elements and in aspects of a redundant operating mode used to serve a degraded geographic service area, the power supply powers both the first set of antenna elements and the second set of antenna elements.

Abstract: In a wireless communication network, an access node controller determines data throughput over a target access node. A source access node wirelessly exchanges user data with User Equipment (UE) and determines data throughput. The source access node receives signal parameters for the source access node and target access node from the UE. The source access node compares the signal parameters and responsively transfers a handover request that indicates the target node and the UE throughput over the source node. The access node controller receives the handover request and compares the source throughput to the target throughput to determine a handover value. The access node controller transfers the handover value to the source access node. The source access node compares the signal parameters based on the handover value, and responsively hands-over the UE to the target access node which wirelessly exchanges user data with the UE.

Abstract: Methods and systems are provided for dynamically modifying a position of an antenna array having a plurality of dipole elements. Initially, it is determined that a quantity of user devices that are attached to the antenna array is at or near a capacity that is able to attach to the antenna array in its current position. An instruction is communicated to rotate the antenna array from a first position to a second position. The current quantity of user devices attached to the antenna array is continually monitored to determine when to instruct that the antenna array be rotated from the second position back to the first position.

Abstract: Methods and systems are provided for dynamically assigning a wireless communication protocol to one or more antenna elements of an antenna array. The methods can include receiving information associated with one or more user devices and, based on the received information, identifying one or more antenna elements of the antenna array, for switching between first and second wireless communication protocols. The methods can also include switching the one or more antenna elements between the first and second wireless communication protocols.

Abstract: An antenna system for a wireless network that provides multi-band and/or multi-sector operation from a single location is provided. The antenna system may provide improved control and adjustment of antennas contained within a compact design to allow sectors of coverage provided by the antennas to be modified to accommodate different cell site parameters that may otherwise have been satisfied using a more distributed arrangement of antennas.

Abstract: Systems and methods are provided for reducing massive multiple-input multiple-output (mMIMO)/5G out-of-band-emission. After detecting interference with an adjacent band, the mMIMO unit (MMU) determines the best corrective action based on calculations to determine if the equivalent isotropically radiated power would still lead to emissions in the adjacent band and, if required, apply one or more corrective actions. In one corrective action, the MMU reduces the overall power by turning off certain power amplifiers driving the dipoles. In another corrective action, the MMU changes the antenna beam width automatically to sway away from the target. In yet another corrective action, the MMU alternates the output power control range. In each of the aspects, the analysis is based on distance and boresight azimuth, as well as location factors. In some aspects, a topographic map of the affected area is utilized to determine clutter so that the selected corrective action is most effective.

Abstract: Methods and systems for mitigating the effects of an atmospheric-based interference event on the propagation of a radio frequency (RF) signal are provided. A wireless communication network may determine, based on internal or external inputs, that a meteorologic condition is likely to occur and that the condition is likely to affect the propagation of an RF signal. In response to the determination and prior to the condition occurring, the network may proactively modify characteristics of the base station propagating the RF signal in order to prevent or mitigate the impact of the interference event on the RF signal's propagation.

Abstract: A wireless communication system to detect a sleepy-cell condition. The wireless communication system comprises a remote radio head that receives network data comprising user data and beamforming instructions from a baseband unit. The remote radio head transfers the user data to wireless communication devices over wireless column beams responsive to the beamforming instructions. The remote radio head further detects a loss of the beamforming instructions for a time threshold and responsively transfers a sleepy-cell alarm indicating the baseband unit.

Abstract: The invention is directed to methods and systems for adjusting the vertical beam width of an imbalanced antenna. In one embodiment, first and second antenna arrays are imbalanced because one of the arrays has at least one more radiating element than the other. The additional gain created by additional radiating element(s) distorts the beam and alters the coverage area of the corresponding array, in embodiments. The tilt of the array having at least one more additional radiating element(s) is modified using phase shifting technology and based on the tilt of the array having fewer elements. By modifying tilt of the array having at least one more additional radiating element(s), the upper 3 dB points of the first and second array may be aligned to correct for the distorted beam and altered coverage area between the first and second arrays.

Abstract: Detection and mitigation of signal conflict, such as a primary synchronization signal conflict, between broadcast cells in a wireless communication network is provided. Multiple broadcast cells may be provided in the network to provide sectors of coverage. A mobile communication device may operate within the network and attempt to attach to one or more of the broadcast cells. A synchronization signal conflict between neighboring broadcast cells may be identified and mitigated using one or more adjustments to the broadcast cells or signals emitted therefrom, which may allow for improved network performance, among other benefits.

Abstract: An antenna system for a wireless network that provides multi-band and/or multi-sector operation from a single location is provided. The antenna system may provide improved control and adjustment of antennas contained within a compact design to allow sectors of coverage provided by the antennas to be modified to accommodate different cell site parameters that may otherwise have been satisfied using a more distributed arrangement of antennas.

Abstract: Devices, systems, and methods for providing improved network performance in wireless communications networks using intelligent radiation selection are provided. A radio is communicatively coupled to an antenna and configured to provide a signal to the antenna for broadcast from a cell site. One or more input components are communicatively coupled to the radio to provide information on at least one of an internal or an external condition of the antenna, so that the radio can adjust or modify the signal provided to the antenna to change an emitted pattern of radiation from the antenna to reduce signal loss, or recover or help maintain an area of coverage provided by the antenna.

Abstract: Detection and mitigation of signal conflict, such as a primary synchronization signal conflict, between broadcast cells in a wireless communication network is provided. Multiple broadcast cells may be provided in the network to provide sectors of coverage. A mobile communication device may operate within the network and attempt to attach to one or more of the broadcast cells. A synchronization signal conflict between neighboring broadcast cells may be identified and mitigated using one or more adjustments to the broadcast cells or signals emitted therefrom, which may allow for improved network performance, among other benefits.

Abstract: A wireless relay mitigates Radio Frequency (RF) interference. A receive antenna receives RF signals over a receive frequency band. An RF receiver processes the received signals to detect and transfer RF interference levels. The processing circuitry transfers control data to a tunable RF isolator that indicates the size of a guard band between the receive frequency band and a transmit frequency band. The guard band size is selected based on the RF interference levels for the receive frequency band at the receive antenna. The tunable RF isolator attenuates RF frequencies in the tunable guard band from corresponding RF transmit signals. A transmit antenna transfers the RF transmit signals over the transmit frequency band.

Abstract: The technology disclosed herein enhances the operation of a wireless access node to dynamically provide transmit power based on Reference Signal Receive Power (RSRP). In one implementation, a method of operating a wireless access node includes transmitting first signals with wireless communication devices using a first transmit power, and identifying RSRP values for the wireless communication devices. The method further includes identifying distances between the wireless access node and each wireless communication device, normalizing the RSRP values based on the distances, identifying a target RSRP based on the normalized RSRP values, and determining a second transmit power based on the target RSRP. The method further provides transmitting second signals to the wireless communication devices using the second transmit power.

Abstract: Methods and systems are provided for modifying spacing in between a plurality of antenna dipole columns on an antenna associated with a wireless communications network. A first signaling technology currently employed by a base station is determined, where the first signaling technology requires each of the antenna dipole columns to be separated from one another by a first distance. It is then determined that a second signaling technology is to be employed by the base station, the second signaling technology requiring each of the antenna dipole columns to be separated from one another by a second distance. A signaling message is communicated to a movement mechanism, causing at least one of the antenna dipole columns to move so that the columns are spaced at the second distance from one another.

Abstract: Devices, systems, and methods for providing improved network performance in wireless communications networks using intelligent radiation selection are provided. A radio is communicatively coupled to an antenna and configured to provide a signal to the antenna for broadcast from a cell site. One or more input components are communicatively coupled to the radio to provide information on at least one of an internal or an external condition of the antenna, so that the radio can adjust or modify the signal provided to the antenna to change an emitted pattern of radiation from the antenna to reduce signal loss, or recover or help maintain an area of coverage provided by the antenna.