An ultra wide band antenna includes a ground plane and an antenna body.

The antenna body includes a planar portion arranged above and parallel to the ground plane. A first tapered portion extends in a perpendicular direction from a first edge of the planar portion towards the ground plane. A lower edge of the first tapered portion is spaced from the ground plane by a predetermined gap. A second tapered portion extends in a perpendicular direction from a second edge of the planar portion towards the ground plane and includes a first portion that is connected to the ground plane.

A multi-band antenna has a feed point, a grounding location, a first portion for low band operation, a second portion for low band operation, and one or more portions for high band operation. The ground reference of the feed point for the multi-band antenna is connected to a separate object that may provide a base for the multi-band antenna. The feed point of the multi-band antenna may be spaced above the base and have a space between the feed point and a location for the ground point. The low band portion has multiple resonances that are often odd multiples of the lowest resonant response. The portions that resonant most dominantly in the high band often have multiple resonances that are even multiples of the lowest high band resonance. The multi-band antenna has resonances spaced closely enough to appear to be a wide band antenna above the fundamental high band resonance.

An external wideband antenna and a wireless communication device are provided in the disclosure. The external wideband antenna includes a radio frequency (RF) coaxial cable, and a first antenna body and a second antenna body which are electrically connected with the RF coaxial cable respectively, where an outer contour of the first antenna body and an outer contour of the second antenna body cooperate to define a tapered slot. In the external wideband antenna provided the disclosure, the outer contour of the first antenna body and the outer contour of the second antenna body cooperate to define the tapered slot, which facilitates generation of a strong coupling current, and in turn a broadening of antenna bandwidth.

A mobile device includes a metal mechanism element, a dielectric substrate, a ground plane, a parasitic radiation element, and a feeding radiation element. A connection end of the parasitic radiation element is coupled to the ground plane. The parasitic radiation element includes a first widening portion, which is positioned at a bend of the parasitic radiation element. The parasitic radiation element has a vertical projection on the metal mechanism element. The vertical projection at least partially overlaps a first closed end of the slot. The feeding radiation element is disposed between the parasitic radiation element and the ground plane. The dielectric substrate is adjacent to the metal mechanism element. The parasitic radiation element and the feeding radiation element are disposed on the dielectric substrate. An antenna structure is formed by the parasitic radiation element, the feeding radiation element, and the slot of the metal mechanism element.

An antenna feed for a stackable antenna system includes a polarization converter that continuously surrounds an omnidirectional antenna. Electromagnetic radiation emitted by the omnidirectional antenna and having an initial polarization passes through the first polarization converter, which converts the initial polarization into a non-vertical linear polarization. A feedline located outside of the first polarization converter forms a helix that wraps around the first polarization converter such that it runs perpendicularly to the non-vertical linear polarization. When the width of the feedline is sufficiently small, electrons in metal of the feedline will not be excited by the radiation, and the radiation will transmit through the feedline with minimal impact on the omnidirectional antenna's gain profile. The feedline may be used to feed a second antenna located vertically above the omnidirectional antenna. When the first polarization converter outputs horizontally polarized radiation, the feedline may form a straight vertical line.

A trifurcated antenna radiator is disclosed. The trifurcated antenna radiator includes a first radiator, a second radiator, and a third radiator. The first and second radiators are coupled to a negative terminal and the third radiator is coupled to a positive terminal. The first radiator includes a first arched element having a first end and a second end and a first apex therebetween. The second radiator includes second arched element having a third end and a fourth end and a second apex therebetween. The first and second radiators may be symmetrical or asymmetrically with respect to each other. The third radiator may be symmetrical or asymmetrical.

A trifurcated antenna radiator is disclosed. The trifurcated antenna radiator includes a first radiator, a second radiator, and a third radiator. The first and second radiators are coupled to a negative terminal and the third radiator is coupled to a positive terminal. The first radiator includes a first arched element having a first end and a second end and a first apex therebetween. The second radiator includes second arched element having a third end and a fourth end and a second apex therebetween. The first and second radiators may be symmetrical or asymmetrically with respect to each other. The third radiator may be symmetrical or asymmetrical.

An antenna device includes a dielectric substrate, an emitting electrode, a power feed circuit that feeds power to the emitting electrode, and a filter circuit formed on a path connecting the emitting electrode to the power feed circuit, the filter circuit is constituted by two or more circuits that are cascade connected, each of the two or more circuits is either a HPF or a LPF, and the antenna device does not have a resonant frequency of the emitting electrode and has two or more resonant frequencies different from the resonant frequency of the emitting electrode, each of which is formed by the emitting electrode and a corresponding one of the two or more circuits.

There is disclosed an antenna arrangement for a portable electronic device, comprising: a ground plane having an edge; and arranged along the edge, in sequence, a feed section, a grounded coupling section, and an extended coupling section. The feed section comprises an RF feed on the ground plane and a feed line extending from the RF feed having a first portion extending substantially perpendicularly from the edge of the ground plane, and a second portion extending from an end of the first portion, substantially parallel to the edge of the ground plane, in a direction away from the grounded coupling section. The grounded coupling section comprises a first conductive element extending substantially parallel to the edge of the ground plane and arranged to overlap or run adjacent to at least a part of the second portion of the feed line of the feed section, and a conductive member to connect the first conductive element to the ground plane. The extended coupling section comprises a conductive meander line extending generally parallel to the edge of the ground plane, one end of the conductive meander line being connected to or configured to couple with a portion of the grounded coupling section, the other end of the conductive meander line being connected to a second conductive element extending substantially parallel to the edge of the ground plane.

An antenna system mounted in a vehicle according to the present invention comprises: a metal plate that forms a part of the exterior of the antenna system and operates as a radiator; a lower substrate disposed on the lower portion of the metal plate; and a first antenna comprising a feeding part disposed on the front surface of the lower substrate and configured to transmit a signal to the metal plate through a metal supporter, and a shorting pin configured to connect the ground of the lower substrate and the metal plate. In addition, the system comprises a second antenna that is disposed in the antenna system and is separately provided from the first antenna.