Abstract: One embodiment is directed to a system comprising a baseband unit (BBU), a cluster of remote radio units (RRUs), and an orchestration module. The cluster of RRUs and BBU communicate with each other over a fronthaul link using an adaptive protocol. The cluster of RRUs is configured to appear as a single base station to a plurality of mobile terminals in connection with providing wireless service to the plurality of mobile terminals. The orchestration module is configured to configure the cluster of RRUs so that a first RRU of the cluster of RRUs transmits first data to a first mobile terminal included in the plurality of mobile terminals and a second RRU of the cluster of RRUs transmits second data to a second mobile terminal included in the plurality of mobile terminals during a same time period using a same frequency.

Abstract: In an embodiment, a remote antenna unit includes a transmitter, a receiver, an antenna, a first interference circuit, and a second interference circuit. The transmitter is configured to generate a transmit signal, and the receiver configured to process a receive signal. The antenna is coupled to the transmitter and the receiver and is configured to radiate a downlink signal in response to the transmit signal and generate the receive signal in response to an uplink signal. The first interference circuit is coupled to the transmitter and the receiver and is configured to receive an analog signal from the transmitter. The second interference circuit coupled to the transmitter and the receiver. The first interference circuit and the second interference circuit are configured to reduce, in the receive signal, interference caused by the transmit signal and/or at least one downlink signal radiated by an antenna.

Abstract: Antennas include first and second radiating elements that are configured to operate in respective operating frequency bands. The first radiating element includes a first dipole arm that has a first conductive path and a second conductive path that is positioned behind the first conductive path. The first conductive path includes a plurality of first segments and the second conductive path includes a plurality of second segments, where a subset of the first segments overlap respective ones of second segments to form a plurality of pairs of overlapping first and second segments. At least some of the pairs of overlapping segments are configured so that the instantaneous direction of a first current formed on the first segment in response to RF radiation emitted by the second radiating element will be substantially opposite the instantaneous direction of a second current formed on the second segment in response to the RF radiation.

Abstract: Base station antennas include a main module that has a first backplane that includes a first reflector. A vertically-extending array of first radiating elements is mounted to extend forwardly from the first reflector, and at least one first RF port is coupled to the vertically-extending array of first radiating elements. These antennas further include a sub-module that is attached to the first backplane. The sub-module includes a second backplane that has a second reflector that is separate from the first reflector. A vertically-extending array of second radiating elements is mounted to extend forwardly from the second reflector and is transversely spaced-apart from the vertically-extending array of first radiating elements. A plurality of second RF ports are coupled to the vertically-extending array of second radiating elements. The vertically-extending array of first radiating elements and the vertically-extending array of second radiating elements are configured to serve a common sector of a base station.

Abstract: A communication system includes remote units to exchange RF signals with mobile devices, at least some of the RF signals comprising information destined for, or originating from, a mobile device. The communication system also includes at least one controller or controller resource communicatively coupled to an external network and configured to assign airlink resources to the user equipment. The at least one controller or controller resource is separated from the remote units by an intermediate network comprising a switched Ethernet network over which data corresponding to the information is carried between the at least one controller or controller resource and the remote units. Two or more of the remote units are configured to belong to the same communication cell. The at least one controller or controller resource is configured to assign two or more of the user equipment in the same communication cell to simultaneously use a same airlink resource.

Abstract: One embodiment is directed to a system comprising a distributed unit (DU) and a plurality of remote units (RUs) to wirelessly transmit and receive radio frequency signals to and from the user equipment using a wireless interface. The DU and RUs are communicatively coupled to each other over a fronthaul and are configured to communicate over the fronthaul using an O-RAN fronthaul interface. Management-plane functionality in the system is configured to define a respective transport flow for one or more processing elements using an RU interface that specifies one or more multicast addresses in order to support multicast transmission from the DU to multiple RUs. In another embodiment, each RU is configured to advertise, during a capability discovery process, capabilities related to implementing a switched network shared cell configuration.

Abstract: Systems and methods for supporting private networks using a DAS are provided. In one example, a method for supporting a private network with a DAS includes determining whether a private network is activated and connected to the DAS. The method further includes determining one or more paths of the DAS impacted by the private network. The method further includes receiving an indication of available resources and capability information for one or more components in the DAS. The method further includes dedicating resources of the DAS to the private network based on requirements of the private network and the available resources for the one or more components of the DAS. The method further includes utilizing the resources of the DAS dedicated to the private network for traffic having an identifier corresponding to the private network.

Abstract: Techniques are provided for determining a resistance of radio power electrical conductors coupling a voltage converter to a radio using electrical parameter(s) obtained from the radio.

Abstract: Devices and methods for retaining, orienting, and/or fanning out flat optical fiber ribbons. The devices are configured to anchor end portions of sheaths holding multiple flat optical fiber ribbons as the flat fiber ribbons enter a fiber management tray via the retaining, orienting, and/or fanning out device.

Abstract: A sealed structure (e.g., sealing module, sealing projection, etc.) transitions the direction of one or more cables passing through the structure. Sealant (e.g., a gel block) is disposed within the structure to seal one or more cables extending along a transition path within the sealed structure. Ducts and/or cables may be anchored to the sealed structure. The sealed structure may be mechanically secured to a closure at a selected rotational orientation.

Abstract: Multi-band phased array antennas include a backplane, a vertical array of low-band radiating elements that form a first antenna beam, first and second vertical arrays of high-band radiating elements that form respective second and third antenna beams and a vertical array of RF lenses. The first, second and third antenna beams point in different directions. A respective one of the second radiating elements and a respective one of the third radiating elements are positioned between the backplane and each RF lens, and at least some of the first radiating elements are positioned between the RF lenses.

Abstract: Systems and methods for using a radio intelligent controller with a distributed antenna system and fronthaul multiplexer/fronthaul gateway (FHM/FHGW) are provided. In one example, a method for using a radio intelligent controller with a DAS includes receiving fronthaul information via an E2 interface from one or more nodes of the DAS included in a system. The method further includes automatically generating one or more operational parameters for one or more components of the system that includes the DAS based on the fronthaul information received via an E2 interface from the one or more nodes of the DAS. The method further includes adjusting operation of one or more components of the system that includes the DAS based on the one or more automatically generated operational parameters for the one or more components of the system that includes the DAS.

Abstract: Methods of powering a radio that is mounted on a tower of a cellular base station are provided in which a direct current (“DC”) power signal is provided to the radio over a power cable and a voltage level of the output of the power supply is adjusted so as to provide a substantially constant voltage at a first end of the power cable that is remote from the power supply. Related cellular base stations and programmable power supplies are also provided.

Abstract: A hybrid coupler is disclosed. The hybrid coupler comprises a printed circuit board having a first metallization layer and a second metallization layer arranged below the first metallization layer. The first metallization layer comprises at least two input ports and at least two output ports. The hybrid coupler further comprises a plurality of couplers coupled adjacent to each other on the first metallization layer. Each coupler of the plurality of couplers comprises transmission traces electrically coupled with the transmission traces of an adjacent coupler and the transmission traces of the plurality of couplers extend between the input ports and the output ports of the first metallization layer. The hybrid coupler furthermore comprises a defective ground structure having a pre-defined shape defined in the second metallization layer below each coupling junction formed between the transmission traces of the plurality of couplers.

Abstract: A multi-band antenna includes a first radiating element that is configured to operate in a first frequency band, a second radiating element that is configured to operate in a second, different frequency band, and a metamaterial adjusting element that is configured to at least partially reflect the electromagnetic radiation in the second frequency band incident on the metamaterial adjusting element such that the reflected electromagnetic radiation is redirected to at least partially cancel the interference of the first radiating element to the second radiating element.

Abstract: A fiber optic cable assembly includes a fiber optic cable and a fiber optic connector. The cable includes a jacket having an elongated transverse cross-sectional profile that defines a major axis and a minor axis. Strength components of the cable are anchored to the connector. The fiber optic connector includes a ferrule defining a major axis that is generally perpendicular to the major axis of the jacket and a minor axis that is generally perpendicular to the minor axis of the jacket. Certain types of connectors include a connector body defining a side opening that extends along a length of the connector body; a ferrule configured for lateral insertion into the connector body through the side opening; and a cover that mounts over the side opening after the ferrule has been inserted into the connector body through the side opening.

Abstract: Aspects and techniques of the present disclosure relate to fiber optic connectors with features that help eliminate the potential of a capillary effect or epoxy wicking. The fiber optic connector may include an epoxy tube with segments that define a pocket in an area that helps to prevent capillary action between components that are otherwise closely positioned.

Abstract: A double flexible optical circuit includes: a flexible substrate supporting a plurality of optical fibers; a first connector terminating the optical fibers at a first end of the double flexible optical circuit; and a second connector terminating the optical fibers at a second end of the double flexible optical circuit. Each of the optical fibers is positioned in one of a plurality of separate extensions formed by the flexible substrate as the optical fibers extend from the first connector to the second connector. The first and second connectors are configured to be tested when the first and second connectors are connected through the double flexible optical circuit. The double flexible optical circuit is configured to be divided in half once the testing is complete to form two separate flexible optical circuits.

Abstract: An antenna includes a radiator that is electrically coupled to a feed stalk having a common-mode rejection (CMR) filter therein. The CMR filter is configured to suppress common mode radiation from the radiator by providing a frequency dependent impedance to a pair of common mode currents within the feed stalk, which is sufficient to increase a return loss associated with the pair of common mode currents to a level of greater than ?6 dB across a frequency range including a frequency of the common mode radiation.

Abstract: Low-band radiators of an ultra-wideband dual-band dual-polarization cellular basestation antenna and ultra-wideband dual-band dual-polarization cellular base-station antennas are provided. The dual bands comprise low and high bands. The low-band radiator comprises a dipole comprising two dipole arms adapted for the low band and for connection to an antenna feed. At least one dipole arm of the dipole comprises at least two dipole segments and at least one radiofrequency choke. The choke is disposed between the dipole segments. Each choke provides an open circuit or a high impedance separating adjacent dipole segments to minimize induced high band currents in the low-band radiator and consequent disturbance to the high band pattern. The choke is resonant at or near the frequencies of the high band.