Abstract: Examples disclose a printed circuit board including an antenna and a matching circuit to match an impedance of the antenna. Further, the examples of the printed circuit board provide the printed circuit board is interchangeable among various types of platforms by adjusting the impedance value of the matching circuit without replacing an electrical component of the matching circuit.

Abstract: A system according to one embodiment includes a phased array antenna comprising a plurality of antenna elements, the plurality of antenna elements configured in a planar array, wherein each of the plurality of antenna elements generates a beam pattern directed at an angle out of the plane of the planar array; and driver circuitry coupled to each of the plurality of antenna elements, wherein the driver circuitry comprises a plurality of transceivers, the plurality of transceivers configured to provide independently adjustable phase delay to each of the plurality of antenna elements.

Abstract: An antenna circuit includes a first antenna tuned to a first fundamental frequency and a second antenna tuned to a second fundamental frequency different from the first fundamental frequency. A first filter has a first terminal connected to the first antenna and attenuates the frequency components outside of a band defined by the first fundamental frequency or its harmonics. A second filter has a first terminal coupled to the second antenna and attenuates the frequency components outside of a band defined by the second fundamental frequency or its harmonics. A passive recombination element couples the second terminals of the two filters to a common terminal.

Abstract: Embodiments are directed to a Radio Frequency Identification (RFID) integrated circuit (IC) having a first circuit block electrically coupled to first and second antenna contacts. The first antenna contact is disposed on a first surface of the IC and the second antenna contact is disposed on a second surface of the IC different from the first surface. The first and second antenna contacts are electrically disconnected from each other.

Abstract: An antenna comprising a first dual delta loop element including a first and a second electromagnetic wave (EM) radiating loop element formed along one axis, where the first and second electromagnetic wave loop elements can be implemented in a delta loop configuration, connected in parallel, and fed in phase. A second dual delta loop element can include a third and a fourth EM radiating loop element formed along an orthogonal axis in the same plane as the first loop. The third and fourth EM loop elements can be implemented in a delta loop configuration, connected in parallel, and fed in phase, where the first dual delta loop element and said second dual delta loop element are disposed in the same plane, having superimposed centers of mass, orthogonal to one another, with related symmetry axis being at ninety degree angle with respect to one another.

Abstract: An electronic device may include a housing having a display opening therein, processing circuitry within the housing, and wireless transceiver circuitry within the housing and coupled to the processing circuitry. The electronic device may also include NFC transceiver circuitry within the housing and coupled to the processing circuitry, a display within the housing and coupled to the processing circuitry, the display having an external surface exposed through the display opening and having an internal surface within the housing, and an NFC antenna positioned within the housing behind and aligned with the internal surface of the display and coupled to the NFC transceiver circuitry.

Abstract: Apparatuses and methods are provided for providing a printed radio frequency identification (RFID) tag assembly. In one exemplary embodiment, the RFID tag assembly includes a substrate including a top surface, and a receiving layer, comprising a plurality of receiving pads having conductive properties, located on the top surface of the substrate. The RFID tag assembly may further include a chip located on the top surface of the substrate. In addition, the RFID tag assembly may include an antenna printed on the receiving layer and bonded to the receiving layer using at least one of a wedge bonding technique and a ball bonding technique. The antenna may include at least one of copper, aluminum, palladium-covered copper, and aluminum-covered copper wire or ribbon.

Abstract: A device, apparatus and method for producing a body or platform interfaced with a wideband antenna system. The antenna interfaces to the body or platform so as to comprise a synergistic radiating system.

Abstract: A radio frequency identification (RFID) device is described. In one or more implementations, the RFID device includes an integrated circuit (IC) die electrically connected to a radio frequency (RF) antenna winding for transmitting electronically stored information via the RF antenna winding. The RFID device also includes a substrate comprising a first core laminated to a second core. The RF antenna winding is routed through the first core and the second core. The first core defines a cavity for retaining the IC die. The cavity is disposed within the RF antenna winding in the first core.

Abstract: An antenna device (10) includes: an antenna (100) including a radiating element (101) and an internal ground (103); a coaxial cable (200) whose internal conductor (204) is connected with the radiating element (101) and whose external conductor (203) is connected with the internal ground (103); and an external ground (500) connected with the external conductor (203) of the coaxial cable (200).

Abstract: A display panel comprises a first substrate and a second substrate which are arranged opposite to each other, and an antenna pattern is formed on the inside or the outside of the first substrate and includes a feed point and a ground point; the feed point is connected with a transceiver in a display device; and the ground point is connected with a ground wire of the transceiver.

Abstract: An antenna sensor includes an antenna operable to receive and/or transmit radio frequency (RF) signals, and one or more sensors operably connected to the antenna and configured to monitor at least one condition and to output sensor signals. A single connection is provided for connection to an electronic device to transfer RF signals from the antenna and sensor signals from the one or more sensors to the electronic device.

Abstract: An embedded high frequency RFID system, method and device comprises a PCB having a non-conductive substrate and conductive traces on the substrate. The non-conductive substrate mechanically supports the PCB and the conductive traces electrically couple electronic components (e.g. microchips, resistors, capacitors) on the board together such that the PCB is able to operate. Additionally, the PCB beneficially comprises a high frequency RFID tag that is embedded within the PCB itself and locked in place by a non-conductive adhesive. As a result, the embedded high frequency RFID system, method and device enables each PCB to store data which gives each PCB sold to a customer a unique ID, which can be read over the life of the product.

Abstract: An apparatus and plurality of sensors where the apparatus includes a plurality of coupling elements; a plurality of attachment portions configured to enable a plurality of sensors to be removably attached to the apparatus; at least one processor; and at least one memory including computer program instructions; wherein the at least one memory and the computer program instructions are configured to, with the at least one processor, enable the apparatus to individually address each of the plurality of coupling elements to obtain a reading from each of the plurality of sensors attached to the apparatus.

Abstract: Multi-layer, multi-material fabrication methods include depositing at least one structural material and at least one sacrificial material during the formation of each of a plurality of layers wherein deposited materials for each layer are planarized to set a boundary level for the respective layer and wherein during formation of at least one layer at least three materials are deposited with a planarization operation occurring before deposition of the last material to set a planarization level above the layer boundary level and wherein a planarization occurs after deposition of the last material whereby the boundary level for the layer is set. Some formation processes use electrochemical fabrication techniques (e.g. including selective depositions, bulk depositions, etching operations and planarization operations) and post-deposition processes (e.g. selective etching operations and/or back filling operations).

Abstract: A wireless communication arrangement (100a) with multiple antennas for a vehicle includes a first printed circuit board (110) having a modem unit (111) and a radiating antenna element (113); a second printed circuit board (120) having a radiating antenna element (123); an interface unit (112) disposed on the first printed circuit board (110) and/or the second printed circuit board (120); and a main bendable portion (130) bendably and electrically connecting the first printed circuit board (110) and the second primed circuit board (120) to each other. The first printed circuit board (110) and the second printed circuit board (120) are mountable on an outer surface of a vehicle in non-horizontal orientation with respect to said outer surface, with the first printed circuit board (110) and the second printed circuit board (120) forming a convex like shape in a horizontal direction via bending of the main bendable portion (130).

Abstract: An antenna structure of a Radio Frequency (RF) device includes an antenna and a transmission line circuit coupled to the antenna. The transmission line circuit includes a plurality of transmission line circuit elements and a transmission line coupling circuit that couples at least one of the transmission line circuit elements together to form the transmission line circuit based on a transmission line characteristic signal.

Abstract: An on-board communication and navigation system for an aircraft is provided for allowing an aircraft to transmit and receive information via satellite link. Specifically, the system includes a radome assembly and a fuselage coupler. The radome assembly, for example, may include an antenna, an antenna control unit and an inertial reference unit. During installation, the fuselage coupler is securely and permanently mounted on the aircraft, typically on the fuselage at the top of the aircraft. Once the fuselage coupler is securely mounted, the radome assembly can be removably attached to the fuselage coupler, allowing the radome assembly to be quickly and easily removed and reattached to the aircraft, as needed.

Abstract: An assembly method for first and second articles is disclosed. A first substrate with a plurality of first articles and a second substrate with a plurality of second articles are selected. The articles on the flexible substrate webs with different pitches are assembled together by displacing portions between the first articles of one web out of plane to move the first articles on that web to the same shorter pitch as the second articles on the other web, aligning the two webs to register corresponding first and second articles on the two webs, and assembling the corresponding articles together. The assembly may be used for example in the making of RFID tags, labels and inlays.

Abstract: An apparatus and method for attaching antennae to RFID tags is disclosed. Included is the use of RFID tags having a symmetrical interconnect system for attaching one or more antennae, such that virtually any rotational orientation of the RFID tag will result in a successful antennae attachment. Two oversized and “L” shaped gold-bumped poles can be arranged on the same side of a chip in an opposing fashion, such that at least one axis of symmetry is formed. Accordingly, virtually all rotational orientations of the chip are then acceptable when attaching a pair of opposing pole antenna leads.

Abstract: A tag assembly is disclosed for attaching an RFID tag including a primary antenna to a flexible surface such as fabric, textile or an item of clothing. The tag assembly has a receptacle including a frame for securely holding the RFID tag, a secondary antenna, and attachment means for attaching the frame to the surface, wherein the frame forms part of the secondary antenna. A method of attaching an RFID tag to a flexible surface is also disclosed.

Abstract: This disclosure provides systems, methods and apparatus for a display device with at least one transparent antenna. In one aspect, a transparent antenna is formed on the surface of a transparent substrate and is cooperatively coupled with a second antenna. The transparent antenna can avoid substantial interference with images produced by the display device.

Abstract: A method for manufacturing inserts provided with an electronic module supporting a chip and an antenna includes supplying top and bottom substrate sheets for a plurality of inserts, said substrates being provided with cavities for subsequently inserting an electronic module in each cavity; providing an antenna for each insert; providing at least one layer of adhesive; providing stacking and assembling by lamination a bottom substrate sheet, a first layer of adhesive, a plurality of antennas, a second layer of adhesive and a top substrate sheet; cutting the laminated assembly to obtain inserts each provided with an antenna; inserting electronic modules in the cavities after the step of laminating the substrate sheets, antennas and layers of adhesive. The method also includes printing the inner surface of at least one of the substrate sheets with a thickness-compensation layer, outside the substrate area intended for receiving the antenna.

Abstract: Systems (300) and methods (900) for packaging an antenna (702) in a communication device (300). The methods involve coupling the antenna to a Printed Circuit Board (“PCB”) such that the antenna is mechanically supported thereby. A hollow shaft (510) of a control knob (304) is positioned over the antenna and at least a portion of PCB (706) such that the antenna is embedded within the control knob. Thereafter, the control knob is mechanically secured to a housing (308) of the communication device. The control knob is arranged such that it can move in a radial direction and a vertical direction (516) relative to the chassis. The control knob is also arranged such that the hollow shaft is able to move freely over the antenna without coming in contact therewith.

Abstract: An antenna system is described which is comprised of an artificial magnetic conductor (AMC), an antenna element, and a feed network comprised of shielded feedlines whose outer conductor, or shield, is routed through the substrate of the AMC. The feedline outer conductor is connected to both the substantially continuous conductive surface and the array of capacitive patches forming the AMC. The shielded feedline suppresses the excitation of undesired TM modes within the AMC substrate, results in a stable return loss over a frequency range associated with the AMC's high surface impedance and surface wave bandgap.

Abstract: A communication terminal device includes a printed wiring board disposed in a casing, a feed pattern provided on a main surface of the printed wiring board, a radiation plate including a substantially planar radiation portion substantially perpendicular to the main surface of the printed wiring board and a lead portion connecting the radiation portion to the feed pattern, and a component mounted on the main surface of the printed wiring board to overlap the lead portion when the main surface of the printed wiring board is viewed from above, the component including a conductive material, a magnetic material and/or a dielectric material. The radiation portion is connected to the lead portion at a side spaced away from the main surface of the printed wiring board, and an area of the lead portion is located at a predetermined distance from the main surface of the printed wiring board.

Abstract: A modal antenna is formed within a battery assembly for use with a portable electronic device. In certain embodiments, the antenna is printed on an exterior surface of a battery enclosure using a conductive ink. In other embodiments, the antenna is attached, or etched, on a substrate; the substrate may at least partially include a battery housing. The antenna can include an Isolated Magnetic Dipole (IMD) antenna, or other radiating structure. Active components, such as active tuning components, are optionally included in the antenna-integrated battery assembly for the purpose of tuning the antenna.

Abstract: According to one embodiment, a chip card is provided comprising a booster antenna wherein the booster antenna comprises a material having an electrical resistivity of at least 0.05 Ohm*mm2/m.

Abstract: An installation includes one or more card cages, which hold antenna array cards for capturing over the air content. The one or more card cages are installed at a cage site, such as a shelter located on the roof of a structure or a floor within the structure. The card cages are powered by a power supply, which is housed within a power supply site. The power supply site is typically a shelter on the roof of the structure or the floor within the structure.

Abstract: A system including a plurality of amplifiers, a plurality of first transmission lines, and a plurality of second transmission lines. The plurality of first transmission lines have first ends respectively connected to outputs of the plurality of amplifiers and second ends connected to a reference potential. The plurality of second transmission lines have first ends connected to a conductor and second ends that are unconnected. Signals output by the plurality of amplifiers to the plurality of first transmission lines are respectively magnetically coupled to the plurality of second transmission lines.

Abstract: A building structure includes a block of building material and a magnetic circuit buried in the block of building material. The structure also includes a plurality of sensing devices buried in the block of building material. Each sensing device may include a contactless power supplying circuit magnetically coupled with the magnetic circuit to generate a supply voltage when the magnetic circuit is subject to a variable magnetic field.

Abstract: A modular RFID tag scanner includes a control unit and multiple signal distribution units. The signal distribution units include multiple antennas within a single housing. The signal distribution units are each connected to the control unit by an RF transmission line. The configuration of the modular RFID tag scanner permits easy construction or retrofitting of a product storage structure to scan RFID tags on products, such as to monitor product inventory on the product storage structure. Methods of installing and using an RFID tag scanner are also disclosed.

Abstract: Systems and methods are provided for operating an existing antenna at a second, higher frequency. To this end, an antenna system includes an antenna feed and a first antenna assembly electrically connected to the antenna feed at a first end. The first antenna assembly has a first electrical length for a first frequency band and includes a substantially linear segment. A second antenna element is connected to the first antenna assembly and extends away from the first end of the first antenna assembly in a direction substantially parallel to the substantially linear segment. The second antenna element has an electrical length of one-quarter of a wavelength associated with a second frequency.

Abstract: A terahertz imager includes an array of pixel circuits. Each pixel circuit has an antenna and a detector. The detector is coupled to differential output terminals of the antenna. A frequency oscillator is configured to generate a frequency signal on an output line. The output line is coupled to an input terminal of the antenna of at least one of the pixel circuits.

Abstract: A wireless communication device and method (600) with enhanced antenna farm, is disclosed. The method (600) comprises: providing (610) a double molded rear housing including a first shot module including an antenna farm located on an interior shell surface and a second shot module; providing (620) a front housing including a user interface configured to allow a user to perform a desired function; and locating (630) a controller between the front and the rear housing, the controller configured to control the operations of a wireless communication device. Advantageously, the method provides a common platform that is universal and easily customizable for any region or desired feature set. Advantageously, the method contributes to allowing an antenna designer enhanced freedom to design an antenna farm, by using the interior shell surface (20) to place antennas.

Abstract: Forming antenna structures having several conductor turns (wire, foil, conductive material) on a an antenna substrate (carrier layer or film or web), removing the antenna structures individually from the antenna substrate using pick & place gantry or by means of die punching, laser cutting or laminating, and transferring the antenna structure with it's end portions (termination ends) in a fixed position for mounting onto or into selected transponder sites on an inlay substrate, and connecting the aligned termination ends of the antenna structure to an RFID (radio frequency identification) chip or chip module disposed on or in the inlay substrate. A contact transfer process is capable of transferring several antenna structures simultaneously to several transponder sites.

Abstract: A flat-conductor connection element for an antenna structure is described. The flat-conductor connection element, is arranged in or on a pane and has: a flat conductor with a base layer, a conductor track, a first dielectric layer, a shield, and a second dielectric layer and a metal frame.

Abstract: An implantable medical device (IMD) includes an electrode that forms a first snap-fit attachment area and an insulator that forms a through-hole, a second snap-fit attachment area and a third snap-fit attachment area. The second snap-fit attachment area mates with the first snap-fit attachment area of the electrode. The IMD further includes a body including an elongated conductive housing and a feedthrough wire extending therefrom. The body forms a fourth snap-fit attachment area on one end that mates with the third snap-fit attachment area of the insulator such that the feedthrough wire extends through the through-hole of the insulator. The housing encloses at least one of a battery, a sensor, and an electronic circuit. The insulator functions to electrically isolate the electrode from the housing of the body.

Abstract: An antenna designing method and a data card single board of a wireless terminal are provided. The antenna designing method provided by an embodiment of the present invention includes: dividing a semi-closed area without other metal wirings on a data card single board of the wireless terminal; and arranging an antenna wiring in the semi-closed area, where a gap exists between the antenna wiring and the data card single board, and the antenna wiring is coupled with the data card single board via the gap. The embodiments of the present invention also disclose a data card single board of the wireless terminal. According to the embodiments of the present invention, a Specific Absorption Rate (SAR) value of the antenna is reduced, and meanwhile, a working bandwidth of a broadband is realized.

Abstract: The present invention relates to a method of manufacturing a metal foil laminate which may be used for example to produce an antenna for a radio frequency (RFID) tag, electronic circuit, photovoltaic module or the like. A web of material is provided to at least one cutting station in which a first pattern is generated in the web of material. A further cutting may occur to create additional modifications in order to provide additional features for the intended end use of the product. The cutting may be performed by a laser either alone or in combinations with other cutting technologies.

Abstract: Systems, methods, and dressings for providing reduced pressure to a tissue site on a patient are presented that involve wirelessly providing power to a reduced-pressure pump. In one instance, a RFID antenna is used to power a reduced-pressure pump that is fluidly coupled by a conduit to a reduced-pressure dressing. In another instance, a reduced-pressure dressing incorporates a micro-pump and a RFID antenna that is used to power the micro-pump. Other systems, methods, and devices are presented.

Abstract: Electronic components each having a chip module with module contacts and an antenna having antenna contacts is made by securing a plurality of the chip modules the inner face of a module film strip having an outer periphery projecting past the chip module with the chip modules spaced from one another at a uniform predetermined module spacing. A plurality of the antennas are secured to an inner face of an elongated antenna strip with the antennas spaced from one another by a predetermined antenna spacing. The module strip is longitudinally subdivided into sections each of which is of a length equal to the predetermined module spacing and each of which carries a respective chip module. The module-strip sections are pressed against the antenna strip such that the module contacts of each of the chip modules engage and bear on the antenna contacts of a respective antenna.

Abstract: A unit configured for implantation in a subject's body may include a carrier, an implantable circuit associated with the carrier, an antenna arranged on the carrier and configured to wirelessly receive energy from a location external to the subject's body and to provide at least a portion of the energy to the implantable circuit, and at least one component associated with the carrier for receiving energy from the implantable circuit. Wherein the implantable circuit and the antenna have an internal resonant frequency mismatched from an external resonant frequency of an external circuit, to account for resonance frequency variation as a result of implantation in the subject's body.

Abstract: A method for attaching antennae to RFID tags is disclosed. Included is the use of RFID tags having asymmetrical interconnect system for one or more antennae, such that virtually any rotational orientation of the RFID tag will result in a successful antennae attachment. Two oversized and “L” shaped gold-bumped holes can be arranged on the same side of the ship in an opposing action, such that at least one axis of symmetry is formed. Accordingly, virtually all rotational orientations of the chip are then acceptable when attaching a pair of opposing pole antenna leads. Alternatively, a pair of poles can be located on opposing chips surfaces, such that antenna substrates can be attached to both the top and bottom of the chip to form a product “sandwich”, whereby the rotational orientation of the chip is irrelevant at an antenna attachment step.

Abstract: The disclosed embodiments relate to a communication device (200) that implements a subset of feature choices selected from a complete set of feature choices. An exemplary embodiment comprises at least one common hardware component (210) common to any subset of feature choices, and a base (102) that is adapted to accommodate installation of at least one optional hardware component (221) associated with at least one feature of the complete set of feature choices.

Abstract: A mobile wireless communications device includes a housing and circuit board carried by the housing. Radio Frequency (RF) circuitry is mounted on the circuit board. A first antenna is supported by the circuit board within the housing and operatively connected to the RF circuitry and configured for cellular phone communications. A second antenna is supported by the circuit board within the housing and operatively connected to the RF circuitry and configured for WiFi communications. The second antenna comprises an inverted-F or monopole antenna having an opening gap that is pointed away from the first antenna.

Abstract: Forming antenna structures having several conductor turns (wire, foil, conductive material) on a an antenna substrate (carrier layer or film or web), removing the antenna structures individually from the antenna substrate using pick & place gantry or by means of die punching, laser cutting or laminating, and transferring the antenna structure with it's end portions (termination ends) in a fixed position for mounting onto or into selected transponder sites on an inlay substrate, and connecting the aligned termination ends of the antenna structure to an RFID (radio frequency identification) chip or chip module disposed on or in the inlay substrate. A contact transfer process is capable of transferring several antenna structures simultaneously to several transponder sites.

Abstract: This disclosure describes an implantable medical lead, and method of making such a lead or components of the lead, that reduces the undesirable effects the fields generated by an MRI device may have on the implantable medical lead and the implantable medical device. The implantable medical lead includes an RF filter placed in series with an electrical path to an electrode of the lead. In one example, the RF filter may comprise a conductor wound in such a manner that it provides an inductance and capacitance that provides the RF filter with a resonant frequency, and in some instances, multiple resonant frequencies. At frequencies around the resonant frequency of the RF filter, the RF filter presents a high impedance, thereby blocking the signal from or at least attenuating the signal propagating to the electrode. At frequencies far from the resonant frequency, the RF filter presents a low impedance.

Abstract: A hybrid electromagnetic bandgap (EBG) structure for broadband suppression of noise on printed wiring boards includes an array of coplanar patches interconnected into a grid by series inductances, and a corresponding array of shunt LC networks connecting the coplanar patches to a second conductive plane. This combination of series inductances and shunt resonant vias lowers the cutoff frequency for the fundamental stopband. The series inductances and shunt capacitances may be implemented using surface mount component technology, or printed traces. Patches may also be interconnected by coplanar coupled transmission lines. The even and odd mode impedances of the coupled lines may be increased by forming slots in the second conductive plane disposed opposite to the transmission line, lowering the cutoff frequency and increasing the bandwidth of the fundamental stopband.

Abstract: An apparatus including an antenna; a first antenna carrier forming a first support substrate for a first portion of the antenna; and a different second antenna carrier forming a second support substrate for a second portion of the antenna. The first and second antenna carriers are coupled to each other. The antenna extends across a joint between the first and second antenna carriers.