Abstract: The present invention provides a flexible film antenna. The flexible film antenna includes a radiating element comprising a conductive trace on a flexible film. Flexible film is mounted on a core. The core comprises at least two parts that are releasably coupled together in snap or sliding relation. A feed post extends out a base of the core to connect to a power feed. Finally, a protective housing can be molded over the antenna.

Abstract: To attain the advantages of and in accordance with the purpose of the present invention, a connector for an antenna is provided. The connector comprises a nut, insulator, contact pin, sleeve, and a captive housing. The connector is such that the housing can be positioned and angled relatively to a radio frequency device as desired and then locked in place by tightening the nut (or interface) on the device.

Abstract: The present invention provides a flexible film antenna. The flexible film antenna includes a radiating element comprising a conductive trace on a flexible film. Flexible film is mounted on a core. The core comprises at least two parts that are releasably coupled together in snap or sliding relation. A feed post extends out a base of the core to connect to a power feed. Finally, a protective housing can be molded over the antenna.

Abstract: An antenna is provided having a relatively wide bandwidth of operation. The antenna may be a printed circuit board dipole antenna having a ladder balun feed network coupled to a ground plane and dipole radiating elements located about one-quarter wavelength from an edge of the ground plane. The ground plane acts as a reflector to increase antenna gain. A plurality of the antennas may be provided in an array configuration with antennas being located in relatively close proximity and being isolated from other antennas in the array. An array of antennas may be used to provide a wireless link in a wireless network utilizing a IEEE 802.1X frequency band.

Abstract: Printed circuit techniques and two-shot molding techniques are used to form a metal radiating element, a metal ground plane element, a metal antenna feed, a metal short-circuiting strip and metal capacitive loading plates within small antennas that are buried within transmit/receive radio-devices such a mobile cellular telephones. Balanced and unbalanced, single-feed, two and three band antennas are provided wherein the radiating element is laterally spaced from the ground plane element, to thereby provide an antenna having a very low profile or height, including antennas wherein the ground plane element and the radiating element are placed coplanar on the same surface of a PCB. A thin dielectric carriage on a PCB allows for the metal capacitive loading plates to be placed on the sidewalls of the dielectric carriage, to thereby provide reactive loading of a radiating element that is on the top surface of the dielectric carriage.

Abstract: The present invention provides a printed circuit board omni directional antenna. The omni directional antenna includes power dissipation elements. The power dissipation elements reduces the impact the power feed to the radiating elements has on the omni directional antenna's radiation pattern.

Abstract: The present invention provides an antenna with an integral electrical connection to a printed circuit board.

Abstract: An internal antenna for wireless devices comprising a ground plane and a planar loop antenna. The shorted loop antenna is provided with a gap and operates at a quarter wavelength. The compact single feed dual or multi band internal antenna is realized either through composite assembly of an active outer and inner radiating elements or by a selective combination of an active outer radiating element and a parasitic inner radiating element. The inner radiating element of the proposed invention is completely encompassed within the outer radiating element. The resonant tuning of the internal antenna is accomplished by means of the matching stub and capacitive loading plates with the matching stubs being entirely internal to the outer radiating element.

Abstract: The performance of a dual band meanderline antenna is improved with the addition of a conductive patch. It is well known that a meanderline antenna will have various resonances. A conductive patch capacitively coupled to the meanderline broadens and move the second resonance frequency. Connecting the conductive patch to a coherent power source causes additional bandwidth enhancements.

Abstract: A Planar Inverted F Antenna (PIFA) and a radio module integrated into a single module. The present invention permits the PIFA to be removably secured on the top of a radio chip module. In one embodiment of the invention, a non-conductive antenna frame is removably secured to a radio chip. A radiating element or “patch” is then secured to the top of the frame. The patch has feed and shorting pins connected thereto. The integrated radio/antenna system can be mounted on a PCB using standard surface-mount techniques and the feed and shorting pins can be soldered to the PCB. In another embodiment of the invention, a cover is removably secured to the frame to retain the patch on the frame. The cover has a window to permit the feed and shorting pins to be soldered to the PCB.

Abstract: Printed circuit techniques and two-shot molding techniques are used to form a metal radiating element, a metal ground plane element, a metal antenna feed, a metal short-circuiting strip and metal capacitive loading plates within small antennas that are buried within transmit/receive radio-devices such a mobile cellular telephones. Balanced and unbalanced, single-feed, two and three band antennas are provided wherein the radiating element is laterally spaced from the ground plane element, to thereby provide an antenna having a very low profile or height, including antennas wherein the ground plane element and the radiating element are placed coplanar on the same surface of a PCB. A thin dielectric carriage on a PCB allows for the metal capacitive loading plates to be placed on the sidewalls of the dielectric carriage, to thereby provide reactive loading of a radiating element that is on the top surface of the dielectric carriage.

Abstract: A Planar Inverted-F Antenna (PIFA) comprising a radiating element, a ground plane located below the radiating element; a through hole located at a position corresponding to the radiating element, a power feeding connector pin at a position corresponding to the radiating element; a through hole at a position corresponding to the radiating element; a conductive shorting post (pin) located at a position corresponding to the radiating element; a right side vertical plane formed along the edge of the radiating element; a left side vertical plane formed along the other edge of the radiating element; a lower horizontal plane formed by bending the left side vertical plane; a slot on the radiating element; and a dielectric block located in the area between the lower horizontal plane and the ground.

Abstract: A unitary assembly provides two virtual planar inverted-F antennas (PIFAs) within a physical volume that is occupied by one of the PIFAs. The virtual two-antenna assembly includes a single RF feed, and provides multiple frequency response in the AMPS, PCS, GSM, DCS and GPS frequency bands. A composite radiating element is supported above a ground plane. A C-shaped slot divides the composite radiating element into an outer radiating element and an inner radiating element. Two metal stubs within a slot-discontinuity of the C-shaped slot physically and electrically connect the outer radiating element to the inner radiating element. An RF feed post connects to the outer radiating element, and both of the inner and outer radiating elements are shorted to the ground plane.

Abstract: A small multi-band planar inverted-F antenna (PIFA) includes a metal radiating element that is physically located above a metal ground plane element, and the space therebetween includes a frequency matching network having a microstrip transmission line that connects an antenna feed to a wireless communications device (WCD) feed. The impedance matching network may include a microstrip impedance transformer whose output provides a 50 ohm connection to the WCD. A number of microstrip stubs are connected to the microstrip transmission line. At least some of the microstrip stubs connect to the microstrip transmission line by way of a LC tank circuit. The LC tanks circuits are responsive to different ones of the multiple frequencies to which the PIFA is responsive, and in this manner the impedance matching network is dynamically reconfigured in accordance with the frequency band currently traversing the microstrip transmission line. The LC tanks circuits include discrete capacitors and inductors.

Abstract: A low-profile, tri-filar, helix antenna having circular polarization (CP) includes a single feed, in the absence of an internal feed network. The antenna includes three metal, bent, quarter-wave monopoles that are physically positioned at 0, 120, and 240 degrees, respectively, on a top flat surface of the antenna. One of the monopoles is directly-fed, and the other two monopoles are parasitically coupled to the directly-fed monopole. Metal perturbations on one or both of the two parasitic monopoles control their coupling-phase to the directly-fed monopole. One of the parasitic monopoles couples at positive 120 degrees to the directly-fed monopole, and the other parasitic monopole couples at negative 120 degrees to the directly-fed monopole. Various perturbation options generate this CP phasing.

Abstract: A disk-shaped two-antenna assembly contains a CP ring-antenna and a linear-monopole-antenna. The bottom surface of a ring-shaped dielectric member holds a ground plane. A circular radiating element is located on a top surface of the ring-shaped dielectric member. A linear radiating element is positioned coincident with a central axis of the two-antenna assembly, and a top end thereof carries a metal disk that extends perpendicular to the central axis of the two-antenna assembly. A centrally-located void lies between the ground plane and the metal disk to provide for the housing of electronic components. Metal RF shields are electrically connected to the ground plane and are located at the top portion of this void, intermediate the bottom-located ground plane and the top-located metal disk.

Abstract: An antenna is responsive to both a low frequency band and a high frequency band. The antenna includes a metal connector and a hollow insulating tube that is supported by the metal connector. A relatively large diameter metal coil that is responsive to the low frequency band is coiled about an outer surface of the insulating tube, and one end of this coil is connected to the metal connector. A relatively small diameter metal coil that is responsive to the high frequency band is coiled adjacent to an inner surface of the insulating tube, and one end of this coil is connected to the metal connector. A metal disk is mounted on and electrically connected to an opposite end of the small diameter coil. A sheath of dielectric material axially compresses the two coils against the metal connector and also provides an outer cover for the antenna.

Abstract: The present invention provides a dual band single center feed dipole antenna by providing a conventional half-wave dipole antenna single band dipole antenna and loading the single band dipole antenna with two open circuit stubs or arms. The two open circuit stubs form a second half-wave dipole that resonates at a second frequency.

Abstract: The present invention provides antenna assemblies for wireless devices where the antenna has a tip with at least one barb and a cap with at least one internal groove. The barb and groove mate to form a snap lock. The snap lock resists pressure tending to pull the cap off the antenna.

Abstract: The present invention provides a support for an antenna. In particular, the present invention provides a substrate with conductive transition pads for a co-linear coaxial antenna array. The transition pads are constructed and arranged to properly provide power and phase shifting to the antenna array.