The present invention includes: a film antenna (10); a cable (20) which is connected to a feed section (14) of the film antenna (10); and a support (30) around which at least part of the film antenna (20) is wound, the support (30) including a holding section for holding the cable (20).

An antenna mounting apparatus for a combine harvester where the apparatus includes a first grain tank extension panel mounted to a frame so as to be moveable between an open, extended, position and a closed, retracted, position. An antenna-supporting bracket is pivotally mounted to the grain tank extension panel around a first pivot axis. Actuation means are provided to pivot the antenna-supporting bracket with respect to the grain tank extension member when the grain tank extension panel moves between the open position and closed position.

In an example embodiment, a waveguide device comprises: a first common waveguide; a polarizer section, the polarizer section including a conductive septum dividing the first common waveguide into a first divided waveguide portion and a second waveguide divided portion; a second waveguide coupled to the first divided waveguide portion of the polarizer section; a third waveguide coupled to the second divided waveguide portion of the polarizer section; and a dielectric insert. The dielectric insert includes a first dielectric portion partially filling the polarizer section. The conductive septum and the dielectric portion convert a signal between a polarized state in the first common waveguide and a first polarization component in the second waveguide and a second polarization component in the third waveguide.

A roof antenna including an antenna base with a base plate, a spindle, a driver arranged on the spindle, and a locking element having a first limb and a second limb. The first limb has a first latching hook and the second limb has a second latching hook. The first limb and the second limb extend through an aperture in the base plate. A translatory movement of the driver on the spindle is transferred into a displacement of the locking element in a displacement direction perpendicular to the base plate.

An antenna mounting bracket assembly for coupling an antenna to a vehicle includes a first plate, a bar, and a coupler. A set of apertures positioned in the first plate is configured to be aligned with hinge holes positioned in an upper hinge. Hinge bolts are insertable through the apertures, the hinge holes, and holes positioned in a door frame of the vehicle so that the first plate is coupled to the vehicle. A spacer is coupled to and extends from a first face of the first plate. The bar is coupled to and extends from the spacer distal from the first plate so that the bar extends between the door frame and a door when the door is closed. The coupler is coupled to the bar distal from the spacer and is configured to couple to a mount of an antenna to couple the antenna to the vehicle.

An antenna assembly includes a base, a lower shell, a heat-dissipating support, an antenna body, and an upper shell. The base includes a base body and a connecting portion connected to each other. The lower shell includes a pivotal base. The pivotal base is located at a first end of the lower shell, and a second end of the lower shell is connected to the connecting portion. The heat-dissipating support includes a bottom portion, a fixed portion, and an extension portion connected in sequence, and the bottom portion is pivotally disposed on the pivotal base. The antenna body includes an adapter board and a first antenna connected to each other. The adapter board includes a fixed end fixed to the extension portion. The upper shell includes an accommodation space configured to accommodate the heat-dissipating support and the antenna body, and the fixed portion is fixed to the upper shell.

In-building antenna apparatus and methods for manufacturing and installing the same. In one embodiment, the antenna apparatus includes a radome cover, a lower flange, an antenna housing, a spring-loaded mount apparatus, a signaling interface, and a plurality of spring arms. Each of the spring arms may include at least one tie-down location. Accordingly, when a removable tie is placed around a plurality of tie-down locations, the antenna apparatus resides in an installation configuration; however, when the removable tie is removed from around the plurality of tie-down locations, the antenna apparatus transitions towards a default configuration. The spring arms may also act as a ground plane for the antenna. Spring-loaded mount apparatus as well as methods of manufacturing and installing the aforementioned antenna apparatus are also disclosed.

Antenna assemblies for vehicles, such as RADAR sensor antenna assemblies. In some embodiments, the assembly may comprise an antenna block defining an array of waveguide grooves on a first side of the antenna block. A slotted layer comprising a plurality of slots may be coupled with the antenna block with the slots at least partially aligned with the waveguide grooves of the antenna block. An adhesive layer may be positioned in between the antenna block and the slotted layer.

In an antenna device, when an AM/FM antenna as a first antenna and an SDARS antenna or a GPS antenna as a second antenna that have different frequency bands are provided in a common case, an additional conductor portion extends out from a conductor main body portion of a capacitive element, and the additional conductor portion includes a parallel strip-shaped portion having a length that is ¼ of an effective wavelength in a frequency band of the second antenna, and extending parallel to the conductor main body portion.

A radio frequency (RF) antenna assembly is mounted on a shielded panel to facilitate the transmission of RF signals therethrough. The RF antenna assembly includes an RF antenna formed from wire which is bent to define first and second antenna elements. The RF antenna is inserted through the panel with the first and second antenna elements disposed on opposite sides thereof. A dome-shaped cap constructed of a compressible elastomeric material is mounted over the first antenna element and lies flush against the outer surface of the panel. A disc-shaped dielectric base receives the distal end of the second antenna element and lies flush against the inner surface of the panel. The RF antenna exerts a spring-like force that resiliently draws the cap and base together. In use, each antenna element transmits RF signals within a designated frequency range to wireless electronic devices located on the same side of the panel.