The present disclosure describes a telecommunications equipment mount. The mount includes a stabilization frame having a bottom and at least three sides, the bottom and sides defining an open interior cavity, at least one mounting member perpendicular to one of the sides of the stabilization frame and extending outwardly from the side of the stabilization frame a distance, and at least one brace member. The at least one brace member includes a first bracket coupled to one side of the stabilization frame and configured to be secured to the at least one mounting member and a second bracket extending outwardly from the same side of the stabilization frame at an angle. A first end of the second bracket is coupled to a lower end of the first bracket and a second opposing end of the second bracket is configured to be secured to the at least one mounting member at a different location than the first bracket. The stabilization frame is configured to ballast the mount on a mounting structure when telecommunications equipment is secured to the mount. Telecommunications equipment mount assemblies are also described herein.

A vehicle, an antenna assembly of the vehicle, and a method of assembling the antenna is disclosed. The vehicle includes a housing having a passage formed therethrough. A circuit board is disposed within the housing. An antenna element is coupled to the circuit board and passes through the passage. A plug fills an annular volume of the passage between the antenna element and the housing.

A positioning unit of an access control and user tracking system includes an antenna, which is embedded in the substrate of a ceiling tile of a drop ceiling system. The antenna can be observable (embedded in the substrate of an exposed surface of the ceiling tile), or, alternately, not observable (concealed within the substrate of the ceiling tile). A pinhole camera for capturing video information is inserted through the substrate of the ceiling tile and protrudes from the exposed surface of the tile. A ground plane covers the unexposed surface of the ceiling tile. A control module, comprising a controller, a network interface, an antenna controller, a power supply, an omni directional antenna and/or memory for the positioning unit, is positioned on the unexposed surface of the tile.

A roof antenna for a vehicle has a cover that is connected to a baseplate via a latching unit. The latching unit comprises latching hooks that releasably engage behind elastic latching lugs.

A magnetic roofing attachment assembly utilizes a magnetic connecting arrangement to support rooftop equipment without mechanically penetrating a waterproof membrane of the roof. First and second members on opposite sides of waterproof barrier are magnetically coupled (connected) through the barrier to secure an external support for rooftop equipment.

A remote antenna unit including at least one antenna configured to enable conversion between a digital signal and a radio signal; an external digital interface for providing the digital signal; and means for adapting performance of the antenna in dependence upon measurement of at least one parameter.

An antenna assembly comprising a base, a modem, a top lid and a housing is disclosed herein. The base is composed of an aluminum material. The modem is disposed on the base. The top lid is for the base, and the top lid comprises at least one antenna element disposed on an exterior surface. The housing covers the top lid and base. The top lid acts as an electro-magnetic barrier for the modem. A communication cable is connected to the modem at one end and extending to and connected to a vehicle internal router with a vehicle modem at the other end.

Disclosed is a vehicle, comprising an antenna apparatus inserted at least in regions into an antenna opening of a vehicle roof of the vehicle. The antenna apparatus having at least one fastening device. The fastening device having a locking lever locking the antenna apparatus to the vehicle roof in a predetermined locking position of the locking lever and thereby fixing the antenna apparatus on the vehicle roof in a predetermined final assembly position. The fastening device having a spring device which acts on the locking lever with a restoring force acting in the direction of the predetermined locking position of the locking lever and holding the locking lever in the predetermined locking position. The spring device engaging around the vehicle roof in the predetermined final assembly position with a latching edge on an edge of the antenna opening and holding the antenna apparatus at least indirectly on the vehicle roof.

An antenna device for a vehicle includes a base plate, an expansion element formed by a first expansion element part and a second expansion element part mated with the first expansion element part, and an actuating element cooperating with the base plate and the expansion element. Each of the first expansion element part and the second expansion element part has a flat area, a side arm protruding at an angle from the flat area, and a laterally open breakthrough in the flat area. The laterally open breakthrough of each of the first expansion element part and the second expansion element part when mated forms a single passage opening for the actuating element.

A connection device on an antenna housings includes a circular mounting platform, a covering cap, and a screw bolt. The circular mounting platform is configured to receive an antenna board on the top side. The bottom side of the mounting platform is provided with reinforcement ribs running radially toward the center. The covering cap is configured to completely cover the mounting platform. The screw-bolt is situated at the center of the mounting platform, and is configured to be inserted into an antenna housing carrier. The connection device is a rotary/latching connection.