Abstract: A microwave antenna assembly and methods of using and/or assembling the same, which may mitigate problems related to tolerance and tolerance stackup. For example, the microwave antenna assembly may include a waveguide that includes a first waveguide component and a second waveguide component; and a mechanical connection configured to couple the first waveguide component and the second waveguide component and configured to force a first gap between the first waveguide component and the second waveguide component. A spanning distance of the first gap may be selected to reduce a size of a second gap due to tolerances within the microwave antenna assembly between the waveguide and radio equipment. The radio equipment may be configured to provide the waveguide with microwave radiofrequency (RF) signals.

Abstract: Techniques are provided for temporarily allocating a new radio controlled by a spectrum access system (SAS) a frequency spectrum in shared spectrum in which to transmit, and a maximum transmit power level. The temporary frequency spectrum and optionally maximum transmit power level may be sent to the new radio so that it can commence transmitting prior to a planned, e.g., periodic, spectrum coordination is performed for all radios which had requested authorization from the SAS to transmit in the shared spectrum.

Abstract: A cable hanger includes: a base panel having opposed ends; a pair of arms, each of the arms attached to a respective end of the base panel and having a free end; a pair of locking projections, each of the locking projections attached to a respective free end of the arms; and a pair of gripping members, each gripping member attached to a respective arm, each gripping member having opposed ends, wherein one of the ends of each gripping member is fixed to the arms and the other of the ends of each gripping member is fixed to the arm or to the base panel. The arms and locking projections are configured to spread apart to enable insertion of a cable between the arms, wherein the gripping projections engage and grip the cable, and wherein the locking projections are configured to be inserted into the aperture of the supporting structure.

Abstract: A low sidelobe beam forming method and dual-beam antenna schematic are disclosed, which may preferably be used for 3-sector and 6-sector cellular communication system. Complete antenna combines 2-, 3- or 4-columns dual-beam sub-arrays (modules) with improved beam-forming network (BFN). The modules may be used as part of an array, or as an independent 2-beam antenna. By integrating different types of modules to form a complete array, the present invention provides an improved dual-beam antenna with improved azimuth sidelobe suppression in a wide frequency band of operation, with improved coverage of a desired cellular sector and with less interference being created with other cells. Advantageously, a better cell efficiency is realized with up to 95% of the radiated power being directed in a desired cellular sector.

Abstract: An insert for mounting multiple cables in a cable hanger includes: a gripping portion configured to engage multiple cables; and a wrapping portion attached to the gripping portion and configured to wrap around the gripping portion as it receives cables.

Abstract: Active antennas are provided. An active antenna includes a main processor that is configured to perform processing of packets from an O-RAN interface of the main processor to provide a plurality of data streams. The active antenna also includes a plurality of secondary processors that are configured to process the data streams from the main processor.

Abstract: A directional coupler includes a primary transmission line electrically coupled in series between an input port and an output port of the coupler, and an asymmetric, meander-shaped, secondary transmission line, which is electrically coupled in series between a coupling port and an isolation port of the coupler. The secondary transmission line includes a first coupling segment, which is reactively coupled to a first portion of the primary transmission line, and a second coupling segment, which is reactively coupled to a second portion of the primary transmission line, and is spaced closer to, or farther from, the primary transmission line relative to the first coupling segment, such that an asymmetry in reactive coupling is present between the first and second portions of the primary transmission line and the secondary transmission line. An intermediate segment is provided, which is electrically coupled in series between the first and second coupling segments.

Abstract: The present disclosure describes strand mounts for small cell radios. The strand mount assembly includes a cable strand and a strand mount. The strand mount includes two or more interconnected frame sections that form a frame, each frame section having opposing sides configured such that one or more small cell radios and/or antennas can be mounted thereto. The strand mount further includes a plurality of mount apertures sized and configured to receive the cable strand. Each of the mounting apertures is collinear with the other mounting apertures to create an unimpeded opening that the cable strand extends through, thereby mounting the strand mount on the cable strand. Alternative strand mounts and strand mount assemblies are also described.

Abstract: Techniques are provided for more efficiently determining frequency spectrum to allocate to General Authorized Access (GAA) citizens broadband radio service device(s) (CBSD(s)). Efficiency is enhanced by reducing a number of protection point(s) analyzed.

Abstract: A mounting device for a base station antenna includes a support member having: a first section, the first section being configured to, in a mounted state of a base station antenna and a holding pole, connect with an inner side of the base station antenna facing the holding pole in an end section of the base station antenna; a second section, the second section being configured to, in the mounted state of the base station antenna and the holding pole, extend from the first section in a direction away from the holding pole and extend beyond an end side of the end section in a longitudinal direction of the base station antenna; and a connecting portion that is connected with the second section and configured to be directly or indirectly connected to the holding pole in the mounted state of the base station antenna and the holding pole.

Abstract: A ganged connector assembly includes: a plurality of coaxial connectors, each of the coaxial connectors connected with a respective coaxial cable extending rearwardly therefrom, each of the coaxial connectors including an inner contact and an outer body that is electrically separated from the inner contact; a shell having a plurality of cavities; and a plurality of rear bodies, each of the rear bodies encircling a respective outer body, each of the rear bodies mounted in a respective cavity of the shell. Each of the rear bodies includes a first locking feature. A second locking feature is located in each of the cavities and is fixed relative to the shell.

Abstract: A mated connector assembly includes: a first connector assembly, comprising a plurality of first coaxial connectors mounted on a mounting structure and a first shell; and a second connector assembly, comprising a plurality of second coaxial connectors, each of the second coaxial connectors connected with a respective coaxial cable and mated with a respective first coaxial connector. The second connector assembly includes a second shell surrounding the second coaxial connectors, the second shell defining a plurality of electrically isolated cavities, each of the second coaxial connectors being located in a respective cavity. In in a mated condition the second shell resides within the first shell.

Abstract: Techniques for generating and executing power consumption profiles for at least one node of a distributed antenna system are described. In executing each power consumption profile, the distributed antenna system can operate with reduced power consumption when advantageous while maintaining appropriate capacity and activity during periods of high activity.

Abstract: A 4.3/10 coaxial connector configured to receive a mating 4.3/10 connector includes: an inner contact; a dielectric spacer; and an outer contact, the dielectric spacer separating the inner contact and the outer contact. The outer contact includes an outer wall and a plurality of spring fingers, the spring fingers configured to deflect radially inwardly when the mating 4.3/10 connector is mated. The connector further comprises blocking structure that prevents mating of a Mini-Din connector.

Abstract: Base station antennas include first and second radio frequency (“RF”) ports and a first antenna array that includes both first and second radiating elements. Each of the first radiating elements includes a first radiator that is connected to the first RF port that is configured to radiate at a first polarization and a second radiator that is connected to the second RF port that is configured to radiate at the first polarization. Each of the second radiating elements includes a first radiator that is connected to the first RF port that is configured to radiate at a second polarization that is different from the first polarization and a second radiator that is connected to the second RF port that is configured to radiate at the second polarization.

Abstract: An antenna assembly includes a backplane and a polymer substrate mounted over the backplane to define an air gap there-between. The polymer substrate supports radiating elements comprising a polymer-based waveguide feed stalk and a polymer-based pair of radiating arms supported by and electrically coupled to the waveguide feed stalk. A conductive layer is formed on the polymer substrate such that the conductive layer faces the backplane. A phase shifter including a movable element such as a dielectric member or trombone member may be positioned in the air gap for adjusting the phase of a radiating element or a phase shifter assembly may be positioned to the back side of the back plane.

Abstract: The present disclosure describes a sector frame antenna mount assembly. The assembly includes an antenna mount, a sector frame, and a pair of offset extension units. The pair of offset extension units are configured to position the sector frame an increased distance from a mounting structure.

Abstract: In one embodiment, a RF signal repeater switchable between SISO and MIMO comprises: a controller; a first transmitter path switchably coupled to first donor and coverage antennas; a second transmitter path switchably coupled to second donor and coverage antennas; a first receiver path switchably coupled to the first donor and coverage antennas; a second receiver path switchably coupled to the second donor and coverage antennas. The controller configures the repeater for a MIMO TDD operating mode by: configuring the first transmitter path and the second receiver path to repeat at least a first MIMO channel of UE uplink RF signals and at least a first MIMO channel of base station downlink RF signals; and configuring the second transmitter path and the first receiver path to repeat at least a second MIMO channel of UE uplink RF signals and at least a second MIMO channel of base station downlink RF signals.

Abstract: The present disclosure describes a grommet. The grommet includes a slot extending the length of a main body which provides an entry point for a cable to be inserted into an interior cavity, a plurality of flex retention members extending into the interior cavity configured to grip and secure the cable, and one or more grip enhancement features residing between an inner surface of the main body and the flex retention members. The grip enhancement features are configured to provide additional support to the flex retention members when a cable is inserted into the interior cavity. The grip enhancement features are coupled to or integral with a respective flex retention member and extend radially outwardly therefrom, and each grip enhancement feature is configured to engage or contact the inner surface of the main body when a larger diameter cable is received within the interior cavity of the grommet.

Abstract: Embodiments described herein provide for a distributed antenna system including a host unit and an active antenna unit (AAU). The AAU is configured to wirelessly communicate with, and to receive uplink radio frequency (RF) signals from, one or more wireless devices. The AAU is further configured to sample the uplink RF signals to generate digitized RF data. The AAU includes an Ethernet interface for receiving Internet Protocol (IP) formatted data from an IP device coupled to the Ethernet interface. The AAU is configured to transport the digitized RF data and the IP formatted data over a transport signal to the host unit, the transport signal including a plurality of bits. The AAU is configured to adaptively adjust the number of bits that are allocated to the digitized RF data and the number of bits that are allocated to the IP formatted data.