The present invention provides an antenna array which includes a structure in the form of a hexagonal pyramid with a flat top surface/facet. According to preferred aspects, the pedestal support of the present invention preferably further includes six side facets which are preferably disposed 60 degrees from each other. Preferably, each side facet preferably supports a patch antenna and the top facet supports a top/zenith antenna. According to a preferred embodiment, the azimuth antennas may be offset from the ground plane by an angle between 20 and 60 degrees. The zenith antenna is preferably substantially parallel to the ground plane.

The present invention provides an antenna array which includes a structure in the form of a hexagonal pyramid with a flat top surface/facet. According to preferred aspects, the pedestal support of the present invention preferably further includes six side facets which are preferably disposed 60 degrees from each other. Preferably, each side facet preferably supports a patch antenna and the top facet supports a top/zenith antenna. According to a preferred embodiment, the azimuth antennas may be offset from the ground plane by an angle between 20 and 60 degrees. The zenith antenna is preferably substantially parallel to the ground plane.

Disclosed are an antenna reflective net and an antenna reflective net mounting structure. Sliding slots are provided on side walls of the antenna reflective net mounting structure respectively. Protrusions of a base of the antenna reflective net slide into the sliding slots, and the size of the sliding slot is adapted to that of the protrusion. The protrusion is fixed in the sliding slot along a direction vertical to the sliding slot. A baffle block is provided at a distal end of the sliding slot. The baffle block restricts the protrusion from sliding along the direction of the distal end. Moreover, a limit part of an elastic pressing member of the antenna reflective net mounting structure restricts the protrusion from sliding along the direction of the entrance end of the sliding slot after the protrusion enters the sliding slot. Therefore, the antenna reflective net is easily mounted in the antenna reflective net mounting structure with high stability.

An over-molded thin film antenna device is provided that can include a core mandrel having a body and a lip, a thin film radio frequency (RF) element wrapped around and supported by the body, an RF connector electrically coupled to the thin film RF element, and an outer layer molded between shutoff surfaces of the core mandrel and over the thin film RF element. The lip can extend over a top of a portion of the thin film RF element to secure the portion of the thin film radio frequency element between the body and the lip.

The present disclosure provides an electronic device with advanced antenna. The electronic device includes: a display screen; a metal frame surrounding a side edge of the display screen; and a connecting component disposed between the side edge of the display screen and a top end of the metal frame; wherein a height of the connecting component is larger than a preset height such that a portion of the side edge of the display screen not facing the metal frame has at least the preset height. Since the height of the connecting component is larger than the preset height such that the area of the portion of the side edge of the display screen which faces directly the metal frame may be smaller than a predetermined value. Thus, interruption between the display screen and the metal frame may be reduced or eliminated.

The present disclosure provides an electronic device with advanced antenna. The electronic device includes: a display screen; a metal frame surrounding a side edge of the display screen; and a connecting component disposed between the side edge of the display screen and a top end of the metal frame; wherein a height of the connecting component is larger than a preset height such that a portion of the side edge of the display screen not facing the metal frame has at least the preset height. Since the height of the connecting component is larger than the preset height such that the area of the portion of the side edge of the display screen which faces directly the metal frame may be smaller than a predetermined value. Thus, interruption between the display screen and the metal frame may be reduced or eliminated.

A radio-frequency device comprises a printed circuit board and a radio-frequency package having a radio-frequency chip and a radio-frequency radiation element, the radio-frequency package being mounted on the printed circuit board. The radio-frequency device furthermore comprises a waveguide component having a waveguide, wherein the radio-frequency radiation element is configured to radiate transmission signals into the waveguide and/or to receive reception signals via the waveguide. The radio-frequency device furthermore comprises a gap arranged between a first side of the radio-frequency package and a second side of the waveguide component, and a shielding structure, which is configured: to permit a relative movement between the radio-frequency package and the waveguide component in a first direction perpendicular to the first side of the radio-frequency package, and to shield the transmission signals and/or the reception signals in such a way that a propagation of the signals via the gap is attenuated or prevented.

An antenna structure with multiple frequency capabilities applied to an electronic device includes frame body, first feed point, a first switch point, and second switch point. The frame body has at least one portion made of metal material and defines two gaps. The frame body between gaps form a first radiation portion. The first feed point from a source feeds current and signal to the first radiation portion. The first switch point and the second switch point are located at two ends of the frame body adjacent to the first gap. The first switch point and the second switch point are grounded through a switch circuit.

An antenna structure with multiple frequency capabilities applied to an electronic device includes frame body, first feed point, a first switch point, and second switch point. The frame body has at least one portion made of metal material and defines two gaps. The frame body between gaps form a first radiation portion. The first feed point from a source feeds current and signal to the first radiation portion. The first switch point and the second switch point are located at two ends of the frame body adjacent to the first gap. The first switch point and the second switch point are grounded through a switch circuit.

An over-molded thin film antenna device is provided that can include a core mandrel having a body and a lip, a thin film radio frequency (RF) element wrapped around and supported by the body, an RF connector electrically coupled to the thin film RF element, and an outer layer molded between shutoff surfaces of the core mandrel and over the thin film RF element. The lip can extend over a top of a portion of the thin film RF element to secure the portion of the thin film radio frequency element between the body and the lip.