Abstract: According to certain embodiments, a system includes a first electronic device and a second electronic device. The first electronic device is detachably and rotatably connected to the second electronic device. The at least two pairs of antennae are arranged such that each antenna exclusively used for transmission respectively faces each corresponding antenna exclusively used for reception between the first and second electronic devices, and the antennae are bilaterally symmetrical with respect to an axis of rotation of the first and second electronic devices.

Abstract: A vertical combiner for an overlapping linear phased array is provided. The vertical vector combiner enables two strip-line signals from different layers to be combined, or divided, by vertical transitions between substrate layers and produce a desired output signal phase. The combiner can terminate in a short to act as an antenna. In an antenna application, the antenna provides multiple substrate layers for each strip-line signal, each having a metal ground plane. The ground planes are be coupled by vertical transitions access enabling a stepped ground within the structure which increases bandwidth. The multi-layer combiner architecture enables integration with phased array feed networks for millimeter wave phased array antennas.

Abstract: A method for adapting an antenna circuit including at least one first capacitive element and an inductive element in series, and at least one second capacitive element having a first electrode connected between the first capacitive element and the inductive element, wherein data representative of the voltage of said first electrode are applied to the second electrode of the second capacitive element.

Abstract: An apparatus comprising: a ground member configured to receive one or more antennas, the one or more antennas being configured to operate in at least a first operational resonant frequency band; and a cover defining an exterior surface of the apparatus and including a conductive cover portion, the conductive cover portion being coupled to the ground member via a first reactive component to form a first resonant circuit configured to resonate at least partially in the first operational resonant frequency band, and via at least a second reactive component to form at least a second resonant circuit configured to resonate at least partially in at least the first operational resonant frequency band.

Abstract: There is provided an excellent wireless communication device that can suitably perform short range communication by using a millimeter wave. Described are a method of generating a whirl of waves and its characteristic of attenuation proportional to a fourth power of a distance when the waves are in a state L=0 or L=±2. Accordingly, instead of an electric field induction antenna that cannot be used in the millimeter wave band, an initiator and a responder are both equipped with an array antenna generating the whirl of waves to perform communication by using the whirl of waves in the state characteristically attenuating in proportion to the fourth power of the distance, so that the party at the other end approaching can easily be detected while at the same time properly restricting a communication area and preventing improper connection.

Abstract: An electronic device may have hybrid antennas that include slot antenna resonating elements formed from slots in a ground plane and planar inverted-F antenna resonating elements. The planar inverted-F antenna resonating elements may each have a planar metal member that overlaps one of the slots. The slot of each slot antenna resonating element may divide the ground plane into first and second portions. A return path and feed may be coupled in parallel between the planar metal member and the first portion of the ground plane. Tunable components such as tunable inductors may be used to tune the hybrid antennas. A tunable inductor may bridge the slot in hybrid antenna, may be coupled between the planar metal member of the planar inverted-F antenna resonating element and the ground plane, or multiple tunable inductors may bridge the slot on opposing sides of the planar inverted-F antenna resonating element.

Abstract: An antenna mast assembly with an alignment plumb is provided which allows for increased speed and accuracy in aligning antenna masts. The antenna mast assembly includes an antenna mast. An upper end of the mast extends in a first direction and a lower end of the mast extends in a second direction with an angle between the first and second directions. The bend in the mast creates the angle between the upper and lower ends. The upper end of the mast is connected to an antenna. The mast also includes an orientation indicator near its lower end and aligned with the first direction. The mast assembly also includes a foot configured to couple the lower end of the mast to a mounting surface and a plumb coupled to the foot. The plumb includes a plumb indicator that aligns with the mast orientation indicator and indicates that the upper end of the mast is orientated vertically.

Abstract: A communication antenna, a method for controlling a communication antenna and a terminal are provided. The communication antenna includes a first passive unit, a stimulation receiving unit, and a second passive unit. The first passive unit and the second passive unit are respectively coupled to ground. The stimulation receiving unit is electrically coupled to a radio frequency module so as to receive an electrical signal transmitted by the radio frequency module. The first passive unit includes a regulating circuit that includes a switch, a controller, and a regulating assembly. The regulating assembly includes a plurality of electronic components. The controller is configured to control the switch to connect one or more electronic components of the regulating assembly to the circuit. The connected electronic components make the communication antenna resonate in one of a plurality of frequency ranges.

Abstract: An antenna array, especially for use with a radio frequency identification reader, includes a ground plane and a pair of concentric, first and second, circular elements mounted at an elevation relative to the ground plane. First ports are arranged along the perimeter of the first element, and second ports are arranged along the perimeter of the second element. Each port conveys radio frequency signals in an operating band of frequencies. Each perimeter is substantially equal to an odd multiple of one-half of a guided wavelength at a center frequency of the respective operating band. Each adjacent pair of first ports, or adjacent pair of second ports, is successively spaced apart by a spacing constituting a whole multiple of one-half of the guided wavelength at the center frequency of the respective operating band. A polarized patch antenna may be positioned within the circular elements.

Abstract: A small-sized ultra-wideband (UWB) antenna includes a radiating unit configured to have a contour of a first shape, a ground unit configured to have a contour of a shape substantially equal to the first shape, and disposed parallel to the radiating unit, at least one shorting pin connected orthogonal to the ground unit and the radiating unit to connect a first area of the ground unit and a first area of the radiating unit, and a feeding unit connected orthogonal to the ground unit and the radiating unit to connect a second area of the ground unit and a second area of the radiating unit.

Abstract: A handheld electronic device is provided. The handheld electronic device includes a front cover forming the front of the handheld electronic device, a back cover forming the back of the handheld electronic device, a side member at least partially surrounding a space between the front cover and the back cover, a display module, housed in the space, with a screen area exposed through the front cover, and a ground plate housed in the space. At least part of the side member and/or the back cover includes a conductive material. The handheld electronic device includes first and second connection terminals electrically connected to the at least part. The at least part forms at least part of an antenna of the handheld electronic device, and comprises first and second areas which are spaced apart from each other. The first area is electrically connected to the second area and the first connection terminal.

Abstract: A method and system for detecting whether the position of a user's hand gripping a mobile communication device chassis affects an external antenna is provided. A sectioned metal band about a periphery of a mobile communication device has a radiating antenna in at least one metal section. The radiating antenna section is bounded on both sides by electrically floating metal sections. Each of the electrically floating metal sections is bounded on the side distal from the antenna section by a ground metal section. Each metal section separated from an adjacent metal section by an insulating gap. Embodiments measure a differential capacitance between the antenna section and the floating metal section and measure a single and capacitance between the floating metal section and the grounded section to determine whether a user's hand is bridging one or more of the insulating gaps.

Abstract: An integrated circuit package comprises an electrically conductive material, a first electrically isolating layer having a first side in contact with the electrically conductive material and a second side opposite to the first side, a second electrically isolating layer stacked at the second side with at least the first electrically isolating layer and arranged at a package side, and an integrated antenna structure arranged between the first electrically isolating layer and the second electrically isolating layer. The electrically conductive material is encapsulated by a dielectric material, arranged to partly overlap the integrated antenna structure, separated from the integrated antenna structure by at least the first electrically isolating layer and arranged to reflect a radio frequency signal received by the electrically conductive material through at least the first electrically isolating layer to the package side.

Abstract: A system that incorporates the subject disclosure may include, for example, a method for electrically coupling a first lower frequency radiator of a first antenna to a first upper frequency radiator of a second antenna via a shared first port, electrically coupling a second lower frequency radiator of the first antenna to a second upper frequency radiator of the second antenna via a shared second port, suppressing, at least in part, with at least one first filter, first signals of the first lower frequency radiator from entering the first upper frequency radiator, second signals of the first upper frequency radiator from entering the first lower frequency radiator, or both, and suppressing, at least in part, with at least one second filter, third signals of the second lower frequency radiator from entering the second upper frequency radiator, fourth signals of the second upper frequency radiator from entering the second lower frequency radiator, or both. Other embodiments are disclosed.

Abstract: A coil module includes a substrate layer, a coil electrode, and a sealing resin layer. The coil electrode includes metal pins that stand on a resin substrate of the substrate layer in such a way that lower end surfaces thereof are exposed on a lower surface of the substrate layer. The sealing resin layer is stacked on the substrate layer and covers the metal pins. Upper end surfaces of the metal pins are exposed on an upper surface of the sealing resin layer. Each of the metal pins and a corresponding one of the metal pins paired therewith are connected to each other on the lower surface of the substrate layer through a lower wiring pattern. Each of the pins and a corresponding one of the metal pins are connected to each other on the upper surface of the substrate layer through an upper wiring pattern.

Abstract: A system and method for testing an antenna feed to be incorporated into an operational antenna is disclosed. The system and method uses a scaled reflector with the antenna feed to permit testing that correlates well with a full sized reflector, yet permits testing in a quiet zone of a compact antenna test range. Embodiments are also disclosed for offset feed designs.

Abstract: Various embodiments are described that relate to an antenna mount. Multiple antennas can be mounted on the antenna mount. These antennas can work together or be independent of one another. In an example of working together, one antenna can be a transmission antenna while the second antenna can be a reception antenna. The transmission antenna and reception antenna can function with regard to the same communication signal.

Abstract: A planar antenna apparatus is provided. The apparatus includes a first radiation unit configured to transmit a signal, a first feed unit configured to feed a current to the first radiation unit and apply the signal to be transmitted to the first radiation unit, a first Radio Frequency (RF) ground to which a plurality of antenna elements are grounded; and a via that connects the first radiation unit to the first RF ground, wherein all of the first radiation unit, the first feed unit, the first RF ground, and the via are disposed on a first plane, and wherein a capacitance value between the first radiation unit and the first feed unit and an inductance value determined by a length and a width of the radiation unit are set as values that cause a resonant frequency in a specific frequency band to be a preset value.

Abstract: A lightweight deployable antenna assembly for, e.g., microsatellites including multifilar (e.g., quadrifilar) antenna (MHA) structures rigidly maintained in an array pattern by a lightweight linkage and collectively controlled by a central antenna feed circuit and local antenna feed circuits to perform phased array antenna operations. The linkage is preferably an expandable (e.g., flexural-scissor-grid) linkage capable of collapsing into a retracted/stowage state in which the MHA elements are maintained in a closely-spaced (e.g., hexagonal lattice close-packed) configuration optimized for payload storage. To deploy the antenna for operation, the linkage unfolds (expands) such that the MHA elements are moved away from each other and into an evenly spaced (e.g., wide-spaced hexagonal) pattern optimized for phased array operations. The MHA structures utilize modified helical filar elements including metal plated/printed on polymer/plastic beams/ribbons, or thin-walled metal tubes.

Abstract: A collar-mountable antenna for transmitting and receiving signals in a downhole environment, in at least some embodiments, comprises a bobbin having an inner surface and an outer surface, each of the inner and outer surfaces defining multiple slots, conductive wire disposed within the multiple slots on the outer surface of the bobbin, and ferrite disposed within the multiple slots on the inner surface of the bobbin.