A remotely controllable antenna mount for use with a wireless telecommunication antenna provides both mechanical azimuth and mechanical tilt adjustment using AISG compatible motor control units and AISG control and monitoring systems to remotely adjust the physical orientation of the antenna. The mount control units are serially interconnected with existing AISG antenna control units (ACU's) which adjust internal electronic tilt of the antenna. The present solution provides the ability to both physically aim the antenna to adjust coverage area and also adjust the signal phase to fine tune the quality of the signal.

A connection device comprises a first interface assembly that is removably connected to a first pre-determined number of first ports of a first radiating element array in an antenna assembly of the base station antenna, a second interface assembly that is connected to a second pre-determined number of second ports of a remote radio head of the base station antenna, and a connection circuit, the connection circuit being connected between the first interface assembly and the second interface assembly so that the first radiating element array and the remote radio head are electrically connected.

An assembly for mounting one or more RRUs to a mounting structure includes: first and second mounting panels, each of the first and second mounting panels having a main body and a flange that extends generally perpendicularly to the main body, the main body including mounting apertures patterned for mounting of an RRU; a mounting foundation having side edges, each of the side edges having an open-ended slot; mounting members extending from the flanges away from the main body of each of the first and second mounting panels, the mounting members configured to enter the open-ended slots on the mounting foundation and slide therein, and fasteners cooperating with the mounting members to mount the mounting panel to the mounting foundation.

In one embodiment of the present disclosure, an antenna assembly includes a plurality of layers defining an antenna assembly including a plurality of PCB layers and a plurality of non-PCB layers, the antenna assembly having a top surface and a bottom surface, and adhesive coupling between the PCB layers and the non-PCB layers.

A handrail mountable wireless components installation apparatus and related method of installation are disclosed. The apparatus/method includes a shell having two parts, a wireless components housing and a lid; and a chassis for the fixedly but detachable mounting within the shell of the wireless electronic components necessary to provide a WiFi signal, as for example a router and an antenna, the chassis equipped with two sets of brackets. One set of brackets provides the anchoring means for the fastening of the lid onto the housing. The second set of brackets allows the enclosure to be mounted on the handrail. Optionally, the chassis is provided with a mounting plate for the mounting of a router and an opening capable of accommodating an antenna without impeding the flow of the antenna signal. Optionally, the weather resistant handrail mountable wireless components installation apparatus also comprises a gasket.

An antenna mount includes first and second tower mounting brackets. A first frame has first and second portions attached to the first and second tower mounting brackets, respectively. A second frame has third and fourth portions attached to the first and second tower mounting brackets, respectively. First and second equipment brackets are attached to the first frame, and third and fourth equipment brackets are attached to the second frame. Optionally, the first and second frames may each be formed as a one-piece continuous bent tube. Optionally, the first portion and the third portion are located side-by-side and clamped to the first tower bracket by a same first clamp, and the second portion and the fourth portion are located side-by-side and clamped to the second tower bracket by a same second clamp. Optionally, each equipment bracket has a frame face and an equipment face, wherein the frame face is orthogonal to the equipment face and extends in a direction which intersects a plane containing the equipment face at an angle of approximately 10 to 80 degrees.

Access points can be mounted in a variety of locations or orientations and can support multiple communications protocols. In some embodiments, an access point includes a main housing and a front housing. The main and front housing are connected by a hinge. A Wi-Fi antenna is included in the front housing in some embodiments. The access point is configured for use in either an open or closed position. When mounted in a vertical position, the front housing can be lowered into a horizontal position, which facilitates a preferred orientation of an antenna with respect to the ground. A first set of cooling fins serves to maintain components of the access point offset from a wall to which the access point is mounted. This facilitates airflow. Additional fins act as a spacer between the main housing and the front housing when the access point is used in a closed position. This facilitates air flow around both sides of the main housing.

An antenna system has high capacity, continuous mobile coverage that is especially beneficial in stadium style venues. The use of a low profile, rail mounted antenna system and the abundance of hand and safety rails enable coverage throughout the venue. The system increases the density of communications antennas throughout the stadium providing significantly enhanced mobile voice and data service to a higher number of users over traditional stadium technology.

Compact lacunated lenses having a lens body with a plurality of input ports, (which may correspond to a predetermined steering angle), a plurality of output ports, and a plurality of holes/openings in the lens body, wherein the openings are arranged through the lens body so that an electromagnetic signal entering the lens body from any one of the input ports will exit from each of the output ports at a time delay corresponding to the predetermined steering angle of the input port from which the electromagnetic signal entered the lens body. The lenses may be used for RF signals between 2 GHz and 30 GHz for beamforming, and may have a diameter of less than 10 cm. The lenses may also be used for amplification. Methods of using these lenses and phase array antennas including these lenses are also described.

The present disclosure describes an antenna mount kit. The antenna mount kit includes pivotally coupled mounting brackets, at least one adjustment bracket, and at least one locking plate. One of the mounting brackets and the at least one adjustment bracket each include a plurality of phase adjustment holes configured to lock an antenna at a desired tilt angle that is adjustable at 1 degree steps for different length antennas. Antenna mount kit assemblies and methods of adjusting the downtilt of an antenna are also provided.