Abstract: Beamforming codebook optimization in a wireless communication system (WCS) is provided. In a WCS, a wireless node (e.g., base station) simultaneously emits multiple reference beams in a coverage area based on a set of codewords that is optimized for a specific number (a full or a partial set) of antenna elements in an antenna array. The wireless node is configured to determine a different set(s) of codewords that are fine-tuned for forming the reference beams from a different number of the antenna elements in the antenna array and steer the reference beams toward identical directions. During deployment of the wireless node, there may be dead zones or low coverage zones. Aspects of the present disclosure facilitate the discovery of these low-coverage zones using feedback from multiple deployed Internet of Things (IoT) devices. Based on the feedback, the codebook of codewords may be optimized to reduce or eliminate such low coverage zones.

Abstract: Autonomous power saving in a remote unit in a wireless communications system (WCS) is provided. The remote unit can be part of a distributed communications system (DCS) in the WCS, wherein the remote unit communicates downlink and uplink communications signals over a set of radio resources based on a non-cooperative connectivity to a signal source. Herein, the remote unit is configured to opportunistically engage in a power saving mode operation without requiring control signaling and/or a real time trigger from the signal source. More specifically, the remote unit is configured to determine an inactivity period(s) in the set of radio resources that is suited for the power saving mode operation and autonomously enter the power saving mode operation during the determined inactivity period(s). By autonomously engaging in the power saving mode operation, it is possible to reduce power consumption in the remote unit and overall operating expense of the WCS.

Abstract: Beamforming codebook optimization in a wireless communication system (WCS) is provided. In a WCS, a wireless node (e.g., base station) simultaneously emits multiple reference beams in a coverage area based on a set of codewords that is optimized for a specific number (a full or a partial set) of antenna elements in an antenna array. The wireless node is configured to determine a different set(s) of codewords that are fine-tuned for forming the reference beams from a different number of the antenna elements in the antenna array and steer the reference beams toward identical directions. During deployment of the wireless node, there may be dead zones or low coverage zones. Aspects of the present disclosure facilitate the discovery of these low-coverage zones using feedback from multiple deployed Internet of Things (IoT) devices. Based on the feedback, the codebook of codewords may be optimized to reduce or eliminate such low coverage zones.

Abstract: Systems and methods for compression and decompression between elements of a wireless communications system (WCS) such as a distributed antenna system (DAS) contemplate performing a fast Fourier transform (FFT) operation before compression and transmission across a transport medium in a DAS. Further, a size of an FFT block may be varied based on latency requirements. For example, the FFT block size may be based on a sampling rate extracted from channel information. By selecting the FFT block size to meet latency requirements, overall throughput across the transport medium may be increased.

Abstract: Multi-data stream and multi-beam beamforming in a wireless communications system (WCS) is disclosed. In the WCS, a wireless node(s) is configured to simultaneously emit multiple radio frequency (RF) beams in multiple intended directions. In this regard, in embodiments disclosed herein, the wireless node(s) is configured to include a beamforming circuit(s), which is configured to process multiple data streams to generate multiple processed streams each bearing the multiple data streams, and an antenna array(s) configured to simultaneously radiate the multiple processed streams to thereby form the multiple RF beams. Specifically, the beamforming circuit(s) is configured to generate each of the processed streams with predefined phase and amplitude to thereby cause the RF beams to be simultaneously formed in multiple elevations and/or azimuth angles.

Abstract: Selective distribution and/or reception of wireless communications signals in a non-contiguous wireless distributed communications systems (WDCS) for reducing downlink transmission power and/or uplink noise is disclosed. A non-contiguous WDCS is a WDCS in which the remote units are clustered such that remote units with contiguous coverage areas receive downlink communications signals serviced by different cells to provide non-contiguous cell coverage areas. In one example, the WDCS is configured to selectively distribute, through each remote unit, only downlink communication signals for the cell that are identified as servicing the user equipment (UE) to conserve downlink power. In another example, the WDCS is configured to selectively receive uplink communications signals from remote units that contain user data from UE. Noise and/or interference signals associated with portions of the uplink communications signals that are not selectively received (e.g.

Abstract: Beamforming codebook synthesis in a wireless communications system (WCS) is provided. A wireless node simultaneously emits multiple reference beams in a coverage area based on a set of codewords that is optimized for a specific number of antenna elements in an antenna array. The wireless node may need to emit the reference beams using a different number of the antenna elements in the antenna array. Herein, the wireless node is configured to determine a different set(s) of codewords that is fine tuned for forming an identical number of the reference beams from a different number of the antenna elements and steered toward identical directions. In addition, the wireless node can dynamically select an appropriate set of codewords in response to different operating conditions. As such, it is possible to switch transparently, from both wireless node and end user perspectives, between different antenna array configurations under different operating conditions.

Abstract: Multi-beam uniform coverage in a coverage cell(s) in a wireless communications system (WCS) is provided. The WCS includes a number of wireless devices that are typically mounted on a fixed structure to provide coverage for user devices. Each wireless device includes one or more antenna arrays. Each antenna array is controlled via a set of codewords to form one or more RF beams to each cover a respective area in a coverage cell. The codewords are predetermined based on fairness and/or leakage constraints such that the RF beams can be formed in desired geometric shapes and steered toward desired directions to provide a uniform coverage in the coverage cell. By forming the RF beams based on the codewords predetermined based on fairness and/or leakage constraints, it is possible to ensure an equal RF power signal level inside the coverage cell and/or reduced power leakage outside the coverage cell.

Abstract: Selective distribution and/or reception of wireless communications signals in a non-contiguous wireless distributed communications systems (WDCS) for reducing downlink transmission power and/or uplink noise is disclosed. A non-contiguous WDCS is a WDCS in which the remote units are clustered such that remote units with contiguous coverage areas receive downlink communications signals serviced by different cells to provide non-contiguous cell coverage areas. In one example, the WDCS is configured to selectively distribute, through each remote unit, only downlink communication signals for the cell that are identified as servicing the user equipment (UE) to conserve downlink power. In another example, the WDCS is configured to selectively receive uplink communications signals from remote units that contain user data from UE. Noise and/or interference signals associated with portions of the uplink communications signals that are not selectively received (e.g.

Abstract: Beamforming codebook synthesis in a wireless communications system (WCS) is provided. A wireless node simultaneously emits multiple reference beams in a coverage area based on a set of codewords that is optimized for a specific number of antenna elements in an antenna array. The wireless node may need to emit the reference beams using a different number of the antenna elements in the antenna array. Herein, the wireless node is configured to determine a different set(s) of codewords that is fine tuned for forming an identical number of the reference beams from a different number of the antenna elements and steered toward identical directions. In addition, the wireless node can dynamically select an appropriate set of codewords in response to different operating conditions. As such, it is possible to switch transparently, from both wireless node and end user perspectives, between different antenna array configurations under different operating conditions.

Abstract: Optimizing power consumption by transmit signal optimization based on temperature in a beamforming antenna array(s) in a wireless communications system (WCS), and related methods and computer-readable media are disclosed. To manage and control the temperature of the wireless device from exceeding a desired temperature limit, a carrier control circuit is provided and configured to selectively control whether received transmit carriers (i.e. channels) are transmitted through the antenna array based on temperature of the wireless device. Heat generated by the wireless device and/or the antenna array is related to the number of carriers transmitted by the wireless device. The carrier control circuit can use temperature information to determine whether any carriers should be blocked (e.g., dropped) from transmission.

Abstract: Time-division duplexing (TDD) detection in wireless distributed communications systems (DCSs) to synchronize TDD downlink and uplink communications. Remote units in the wireless DCS include an adaptive TDD communications synchronization circuit that includes a power detection circuit configured to detect TDD communications signals distinguished from noise. The power detection circuit is configured to adaptively set a noise threshold floor level for TDD downlink communications link by detecting the noise level on the TDD downlink communications link that includes a TDD uplink communication period. The adaptive TDD communications synchronization circuit can also include a symbol edge detection circuit configured to generate an edge trigger signal indicating the symbol edges of TDD downlink communication signals.

Abstract: Systems and methods for compression and decompression between elements of a wireless communications system (WCS) such as a distributed antenna system (DAS) contemplate performing a fast Fourier transform (FFT) operation before compression and transmission across a transport medium in a DAS. Further, a size of an FFT block may be varied based on latency requirements. For example, the FFT block size may be based on a sampling rate extracted from channel information. By selecting the FFT block size to meet latency requirements, overall throughput across the transport medium may be increased.

Abstract: Systems and methods for compression and decompression between elements of a wireless communications system (WCS) such as a distributed antenna system (DAS) contemplate performing a fast Fourier transform (FFT) operation before compression and transmission across a transport medium in a DAS. Further, a size of an FFT block may be varied based on latency requirements. For example, the FFT block size may be based on a sampling rate extracted from channel information. By selecting the FFT block size to meet latency requirements, overall throughput across the transport medium may be increased.

Abstract: Multi-beam uniform coverage in a coverage cell(s) in a wireless communications system (WCS) is provided. The WCS includes a number of wireless devices that are typically mounted on a fixed structure to provide coverage for user devices. Each wireless device includes one or more antenna arrays. Each antenna array is controlled via a set of codewords to form one or more RF beams to each cover a respective area in a coverage cell. The codewords are predetermined based on fairness and/or leakage constraints such that the RF beams can be formed in desired geometric shapes and steered toward desired directions to provide a unform coverage in the coverage cell. By forming the RF beams based on the codewords predetermined based on fairness and/or leakage constraints, it is possible to ensure an equal RF power signal level inside the coverage cell and/or reduced power leakage outside the coverage cell.

Abstract: Coverage cluster-based beamforming in a wireless node in a wireless communications system (WCS) is provided. In a conventional beamforming system, a wireless node (e.g., base station) periodically emits multiple reference beams, each steered toward a predefined direction, to provide a blanket coverage in a coverage area. Contrary to providing the blanket coverage, a wireless node disclosed herein is configured to provide targeted coverage in a coverage area. Specifically, the wireless node is configured to dynamically group multiple coverage points (e.g., user equipment, high user density area, etc.) into multiple coverage clusters. Accordingly, the wireless node can form and steer a respective reference beam toward each of the coverage clusters.

Abstract: A multi-operator radio node for a communication system that supports sharing a common antenna array while supporting multiple service providers. The multi-operator radio node includes signal processing circuits for each supported service provider. Each signal processing circuit is configured to receive communication signals for a supported service provider to be distributed through a common antenna array to wireless client devices. Each signal processing circuit includes a modem that processes the received communication signals for spectrum of its service provider to provide signal streams to be distributed to co-located antenna elements in the antenna array. Summation circuits are provided at the front end of each RF chain circuit to combine signal streams of the spectrum of the service providers directed to the same antenna element in the antenna array to form signal beams in individual frequencies of the service providers.

Abstract: Autonomous power saving in a remote unit in a wireless communications system (WCS) is provided. The remote unit can be part of a distributed communications system (DCS) in the WCS, wherein the remote unit communicates downlink and uplink communications signals over a set of radio resources based on a non-cooperative connectivity to a signal source. Herein, the remote unit is configured to opportunistically engage in a power saving mode operation without requiring control signaling and/or a real time trigger from the signal source. More specifically, the remote unit is configured to determine an inactivity period(s) in the set of radio resources that is suited for the power saving mode operation and autonomously enter the power saving mode operation during the determined inactivity period(s). By autonomously engaging in the power saving mode operation, it is possible to reduce power consumption in the remote unit and overall operating expense of the WCS.

Abstract: Systems and methods for compression and decompression between elements of a wireless communications system (WCS) such as a distributed antenna system (DAS) contemplate performing a fast Fourier transform (FFT) operation before compression and transmission across a transport medium in a DAS. Further, a size of an FFT block may be varied based on latency requirements. For example, the FFT block size may be based on a sampling rate extracted from channel information. By selecting the FFT block size to meet latency requirements, overall throughput across the transport medium may be increased.

Abstract: An electronic device is described which has a sensor panel comprising a plurality of receive electrodes configured to measure signals received from one or more transmit electrodes. The device has a sensor panel control module configured to: receive signals from the plurality of receive electrodes in the presence of at least one tone interferer. The module is configured to convert the received signals from a time domain into a frequency domain; and to process the received signals in the frequency domain in order to mitigate the effect of the tone interferer.