Abstract: To provide a transmission-line conversion structure for a millimeter-wave band capable of being easily manufactured with a small size without easily causing non-uniformity in characteristics in a wide band. A transmission-line conversion structure for a millimeter-wave band that connects a microstrip line (10), which includes a main conductor (12) formed on one surface of a dielectric substrate (11) and a ground conductor (13) formed on the other surface thereof, with a waveguide (20) has a waveguide structure in which a transmission line (31) having a predetermined length is formed so as to be surrounded by metal walls (32). The transmission line is filled with a dielectric material having a relative permittivity of greater than 1. The transmission-line conversion structure allows electronic waves of a millimeter-wave band in a longitudinal direction of the main conductor.

Abstract: Antenna carriers with magneto-dielectric material and beam-shaping elements for enhanced performance and radiation safety of electronic devices are described. One electronic device includes a housing, an antenna element disposed on an antenna carrier, and a printed circuit board (PCB) disposed within the housing, the printed circuit board including radio frequency (RF) circuitry. The antenna carrier can be made up of a plastic cap, a ground plane, and a magneto-dielectric substrate with both dielectric and magnetic properties. The plastic cap is disposed at a first side of the housing and the magneto-dielectric substrate is disposed on a top surface of the plastic cap. The antenna element is disposed on a bottom surface of the magneto-dielectric substrate and electrically coupled to the RF circuitry. The antenna element radiates electromagnetic energy in a resonant mode and the magnetic property of the magneto-dielectric material increase efficiency, frequency bandwidth, or both.

Abstract: The improved dryer output exhaust duct of the present invention is comprised of a nonconductive, high temperature polymer to form a dielectric exhaust output duct. The dielectric dryer exhaust duct prevents the travelling of electrical current from an inadvertently energized dryer chassis to the attached flexible ducting and thus prevents the ducting from overheating or melting from the electrical current or igniting flammable materials nearby or contained within the ducting.

Abstract: The present disclosure provides an array antenna. The array antenna includes a cavity power divider that receives an input signal and performs power division to output a first power-divided signal. The array antenna also includes a final-stage power dividing, coupling, and radiating unit that includes a dielectric substrate and a first and a second metal surface layer. A coupling slot array is formed on the second metal surface layer to receive the first power-divided signal. A radiating slot array corresponding to the coupling slot array is formed on the first metal surface layer; Several plated through-hole units are provided on the dielectric substrate, where the plated through-hole units go through the first and second metal surface layers vertically, and a range corresponding to each plated through-hole unit encloses a coupling slot and a radiating slot corresponding to the coupling slot.

Abstract: The invention relates to a passive repeater for forwarding radio signals from a first device having a radio interface to a second device having a radio interface, wherein the passive repeater is configured to forward radio signals between an interior of a housing, which has a housing wall acting as a radio barrier, and an exterior, through the housing wall, wherein the passive repeater has a first antenna and a second antenna for this purpose, which are connected to each other by a passive and galvanic coupling, and wherein the first antenna can be arranged in the interior and the second antenna can be arranged in the exterior, and the passive coupling can be carried out through an opening in the housing wall, and wherein the first antenna can be inserted into the interior from the exterior through the opening and/or the second antenna can be withdrawn from the interior to the exterior through the opening.

Abstract: The invention concerns a device for stripping electric cables, comprising at least one stripping beam (10, 11; 110, 111; 209) emitted by a LASER source (1; 101; 201) and focused by an optical assembly (2-4; 102, 103; 203-208) into a focusing point (12, 13), called cutting point, and at least one track (6; 106) for receiving a portion of cable to be stripped, characterised in that each LASER source comprises a LASER diode (1; 101; 201) emitting a stripping beam of which the wavelength is between 400 nm and 460 nm, and preferably of the order of 445 nm.

Abstract: Disclosed is a litz wire coil that is configured by spirally winding a litz wire on one plane by a predetermined number of turns. The litz wire is configured by twisting together a plurality of enameled wires formed by baking an insulating film on a conducting body. Pressure shaping is performed such that the litz wire has a substantially rectangular shape in cross section, and the flatness ratio of the litz wire in cross section (long side/short side) is controlled at 1.10 to 1.60, preferably 1.20 to 1.40, more preferably 1.25 to 1.35.

Abstract: A method for inductively coupled communication is described. The method includes generating a first signal. The first signal frequency is a first integer multiple of a carrier frequency for inductively coupled communication. The method also includes selecting between a standalone mode and a coexistence mode. The method further includes dividing the first signal to obtain a second signal when in standalone mode. The second signal frequency is a second integer multiple of the carrier frequency. The method additionally includes dividing the first signal to obtain a third signal when in coexistence mode. The third signal frequency is a third integer multiple of the carrier frequency. The method also includes generating an inductively coupled communication signal using at least one of the second signal and the third signal.

Abstract: A system includes a sensor body that has a folded optical waveguide configured in a “U” shape, wherein the waveguide is configured to convey infrared energy from one end of the waveguide to the other end of the waveguide.

Abstract: A method of attaching wire to an exposed surface of an adhesive layer includes guiding wire from a wire source through a payout head and through a foot of a write head. A first portion of the wire extends from the foot toward the adhesive layer. The write head is positioned such that a gap between the foot and the exposed surface of the adhesive layer is greater than a diameter of the wire. The write head is moved in a motion parallel to the adhesive layer, and the first portion of the wire adheres to the adhesive layer. Wire is pulled from the wire source by the payout head as the write head is moving in order to maintain slack in a second portion of the wire between the payout head and the write head as the wire is attached to the exposed surface of the adhesive layer.

Abstract: The multi wavelength laser device includes a laser light source 10 that emits a plurality of laser lights 20 whose fundamental wavelengths differ from one another, a dispersing element 30 that changes the traveling direction of each of the plurality of laser lights according to the wavelength and the incidence direction, and that emits the laser lights in a state in which the laser lights are superposed on the same axis, and a wavelength conversion element 40 that has a plurality of polarization layers disposed therein and having different periods, and that performs wavelength conversion on the fundamental wave laser lights emitted from the dispersing element 30 and placed in the state in which the laser lights are superposed on the same axis, and emits a plurality of laser lights 50 acquired through the wavelength conversion in a state in which the laser lights are superposed on the same axis.

Abstract: An antenna device includes a resin multilayer board in which a plurality of resin sheets are stacked, and a coil conductor provided in the resin multilayer board. A plurality of line portions of the coil conductor are provided on a lower surface of the resin sheet. When a magnetic material core is preliminarily pressure-bonded to the resin sheet, the magnetic material core is fractured along the line portions and cracks occur. Thus, the resin sheet with the magnetic material core in which the cracks have been formed is fully pressure-bonded together with the other resin sheets.

Abstract: A beam-steering optical transceiver is provided. The transceiver includes one or more modules, each comprising an antenna chip and a control chip bonded to the antenna chip. Each antenna chip has a feeder waveguide, a plurality of row waveguides that tap off from the feeder waveguide, and a plurality of metallic nanoantenna elements arranged in a two-dimensional array of rows and columns such that each row overlies one of the row waveguides. Each antenna chip also includes a plurality of independently addressable thermo-optical phase shifters, each configured to produce a thermo-optical phase shift in a respective row. Each antenna chip also has, for each row, a row-wise heating circuit configured to produce a respective thermo-optic phase shift at each nanoantenna element along its row. The control chip includes controllable current sources for the independently addressable thermo-optical phase shifters and the row-wise heating circuits.

Abstract: An antenna assembly for a mobile device comprising a printed circuit board and an antenna structure located at a distance from the printed circuit board. The antenna structure is electrically connected to the printed circuit board via at least one elastomeric connector comprising a plurality of conductive filaments and an insulating structure extending between the antenna structure and the printed circuit board.

Abstract: The present disclosure relates to a wireless communication structure, including a plate, a first antenna, a first magnetic material layer, and a second magnetic material layer. The plate has a first surface, a second surface opposite to the first surface, and a lateral surface extending between the first surface and the second surface. The first antenna is located in the plate. The first magnetic material layer is adjacent to the lateral surface of the plate. The second magnetic material layer is located on the second surface of the plate.

Abstract: RFID tag structures are disclosed. In one embodiment, the RFID tag includes a flexible substrate, a strap attached to the substrate, an RFID IC mounted on the strap, and an antenna. The strap has a first surface, a second surface, and first and second terminals exposed on the first surface. The second surface of the strap is attached to the substrate. The RFID IC is electrically coupled to the first and second terminals. The antenna is attached to the first surface of the flexible substrate and connected to the first and second terminals on the first surface of the strap.

Abstract: A digital system has a substrate having a top surface on which a waveguide is formed on the top surface of the substrate. The waveguide is formed by a conformal base layer formed on the top surface of the substrate, two spaced apart sidewalls, and a top conformal layer connected to the base layer to form a longitudinal core region. The waveguide may be a metallic or otherwise conductive waveguide, a dielectric waveguide, a micro-coax, etc.

Abstract: Various embodiments provide for waveguide assemblies which may be utilized in wireless communication systems. Various embodiments may allow for waveguide assemblies to be assembled using tools and methodologies that are simpler than the conventional alternatives. Some embodiments provide for a waveguide assembly that comprises a straight tubular portion configured to be shortened, using simple techniques and tools, in order to fit into a waveguide assembly. For instance, for some embodiments, the waveguide assembly may be configured such that the straight portion can be shortened, at a cross section of the portion, using a basic cutting tool, such a hacksaw. In some embodiments, the straight portion may be further configured such that regardless of whether the straight tubular portion is shortened, the waveguide assembly remains capable of coupling to flanges, which facilitate coupling the straight tubular portion to connectable assemblies, such as other waveguide assemblies, radio equipment, or antennas.

Abstract: During a process for manufacturing an antenna, which includes a core of filiform shape and which is intended to be integrated into a rubber compound of a tyre, the core is coated with a coating made of a material different from a material of the core. After the core is coated, at least one portion of the coated core is plastically deformed.

Abstract: An antenna includes a core and is intended to be integrated into a rubber compound for a tire. The antenna further includes an electromagnetic-signal conduction layer, which is made of copper and coats the core, and a chemical isolation layer, which coats the conduction layer and is intended to chemically isolate the rubber compound from an object coated by the isolation layer.

Abstract: An apparatus includes an antenna structure with a core shaped as a toroid that is designed to be worn on a human digit. A first and second contact are located on the core. A conductive path connects the first contact and the second contact and includes a first set of windings that traverse a circumference of the core in a substantially parallel manner; and a second set of windings that traverse the circumference of the core in a substantially parallel manner. The windings are such that, from a vantage point exterior to the core, the first set of windings is substantially perpendicular to the second set of windings.

Abstract: A connector for data transmission at an interface between two apparatuses for food production, such as meat and sausage production, having a first connecting element connected to the first apparatus and being at least one first data transmission part, a second connecting element connected to the second apparatus and being at least one second data transmission part, the first data transmission part being galvanically isolated from the second data transmission part such that data transmission from the first connecting element to the second connecting element is effected in a galvanically isolated manner.

Abstract: Antenna structures may be customized to compensate for manufacturing variations in electronic device antennas. The antenna structures may include an antenna resonating element and a ground. Customizations may be made to the antenna structures by performing customization operations such as adding material, removing material, deforming material, and making electrical adjustments. Customizations may be performed to a conductive antenna resonating element structure, to a ground structure, or to associated antenna structures such as parasitic antenna elements. During manufacturing operations, antenna structures may be characterized by making radio-frequency antenna performance measurements. Antenna performance can be compared to desired performance levels and compensating customizations for the antenna structures can be identified. Customized antenna structures can be installed in electronic devices during manufacturing to produce devices that meet desired specifications.

Abstract: An integrated circuit (IC) module for a dual-interface smart card includes a planar, non-conductive module tape that is plated on its top surface to define a plurality of conductive contact pads. An IC chip is mounted on the bottom surface of the module tape and is electrically connected to each of the contact pads by a wire, the underside of each contact pad being exposed for bonding with the wire by punching a hole through the tape. The IC chip and wires are protected by an encapsulant. A pair of the contact pads, which are not required to transmit signals through direct contact, is designated as antenna contact pads. Accordingly, a hole is punched through the module tape in alignment with each antenna contact pad outside the region of the encapsulant, thereby rendering the underside of the antenna pads available for connection to an antenna by a conductive element.

Abstract: A ridged waveguide slot array includes a waveguide slot body having one or more walls that define a longitudinal axis of the waveguide slot body. The waveguide slot body includes a narrowed waveguide section having a plurality of slots disposed thereon which extend along the longitudinal axis, the waveguide slot body further characterized by a longitudinal center line. The waveguide slot body defines a waveguide aperture having a major dimension and a minor dimension, wherein the major dimension of the waveguide aperture is less than one-half wavelength of a signal intended for propagation therein. Each slot of the plurality of slots is characterized by a slot area, a slot offset distance that extends from the center of the slot to the longitudinal center line, and a slot-to-slot separation distance extending from the center of the slot to the center of an adjacent slot.

Abstract: A radiation pattern insulator and an antennae system thereof are proposed. The radiation pattern insulator includes a dielectric substrate and a plurality of radiation pattern insulation elements. The dielectric substrate allocated between a plurality of antennae includes a top surface and a bottom surface, and a normal direction of the dielectric substrate is substantially perpendicular to propagation directions of electromagnetic waves radiated from the antennae. In addition, the radiation pattern insulation elements are allocated on the top surface or the bottom surface of the dielectric substrate, or alternatively, all allocated on the top surface and the bottom surface.

Abstract: The invention relates to a portable electronic device comprising a supporting member receiving on one side conductive contact lands or tracks extending substantially as far as the edge of the side and connecting an electronic microcircuit, the conductive contact lands or tracks comprising a plurality of perforations. The device is noteworthy in that the interior of the perforations is free, or intended to be kept free, of metal.

Abstract: A power measurement system includes: a power temperature converter attached to a power supply line of an electric instrument and having a temperature changed corresponding to a current flowing through the power supply line; a temperature measurement apparatus configured to measure the temperature of the power temperature converter; and an analyzer configured to analyze power consumed by the electric instrument by using a measurement result of the temperature of the power temperature converter obtained by the temperature measurement apparatus.

Abstract: A turntable assembled from a plurality of flat sheet metal parts where the sheet metal parts include a series of voids and/or protrusions. The protrusions insert into the voids so that some flat sheet parts are disposed in a vertical orientation and some in a horizontal orientation, the vertical parts substantially perpendicular to the horizontal parts. The flat sheet parts are welded together to create a support structure with the voids and protrusions interacting to align the flat sheet parts within required manufacturing tolerances. One of the horizontally disposed parts has holes therein for attaching the support structure to a hub to create a rotating turntable.

Abstract: An exemplary tracking device or system includes: a radio frequency identification (RFID) circuit disposed on a substrate; an encapsulation cap encapsulating the RFID circuit and substrate; and, an information bearing indicia (IBI) disposed on the encapsulation cap, the RFID circuit and IBI providing at least some similar information when read with a respective reading device.

Abstract: An antenna device of a mobile communication terminal is provided, the device including at least one radiation pattern and at least one magneto dielectric module or dielectric module installed in a selected position on the radiation pattern to tune one or more resonance frequencies of the radiation pattern according to resonance frequencies required for the terminal. The radiation pattern is selected from among one or more radiation patterns fabricated according to a usable frequency band. The one or more radiation patterns each include one or more resonance frequencies. The magneto dielectric module is selected from among one or more magneto dielectric modules fabricated for controlling the one or more resonance frequencies of the one or more radiation patterns. The dielectric module is selected from among one or more dielectric modules fabricated for controlling the one or more resonance frequencies of the one or more radiation patterns.

Abstract: The present invention is a method for producing ready to use RFID devices in a convenient and economical manner. The method in one embodiment includes a substrate having a first a second face and applying a pattern of adhesive to the first face of the substrate. A conductive foil is then laminated to the pattern of adhesive, and the conductive foil is cut to form a plurality of antenna patterns. A chip is applied to each of the antenna patterns. Printing is applied on the second face of the substrate to create distinct printed areas. Each of the printed areas is then read and the information is matched with each of the distinct printed areas to information encoded in each of the chips. Finally, each distinct printed area is separated from the substrate.

Abstract: The invention relates to a method for contacting a chip with a conductor arrangement and also to a conductor arrangement, particularly a transponder antenna, an intermediate carrier or the like, with a carrier substrate (55) for accommodating the chip and with a chip having chip terminal faces formed thereon, wherein a conductor material layer (66) is formed on the carrier substrate, wherein the conductor material layer forms a conductor arrangement (64) having at least two conductors (56, 57) which are connected to each other in a chip contact area (58), wherein an insulating gap (59) is formed in the chip contact area, such that mutually electrically insulated conductor terminal faces (60, 61) of the conductors are formed, wherein the chip terminal faces are contacted with the conductor terminal faces, and wherein the insulating gap is formed by removal of the conductor material layer by means of a laser.

Abstract: Provided is an optical transmitter module. The optical transmitter module includes a package including a lower substrate and a side substrate in which a through hole is formed, and a feed-through block coupled to the side substrate in which the through hole is formed. The feed-through block includes a feed-through substrate, at least one lead pin penetrating the feed-through substrate and coupled to the feed-through substrate, a base substrate formed to extend from the feed-through substrate in a direction in which the at least one lead pin is coupled, and a dielectric substrate formed between the at least one lead pin and the base substrate protruding from the feed-through substrate. Therefore, it is possible to improve the quality of a signal transmitted by the optical transmitter module.

Abstract: An antenna mounting apparatus (10) in which an antenna bracket (32) can be rotated relative to a mount (20) in an azimuth direction and is selectively, automatically locked in position.

Abstract: A circularly polarized artificial impedance surface antenna (AISA) includes an impedance modulated substrate having a modulated scalar impedance to a surface wave traversing a top surface of the substrate, wherein the impedance modulation has a plurality of intertwined lines of constant impedance, and wherein each line of constant impedance follows a spiral elliptical path.

Abstract: An RF aperture coldplate for positioning in heat transfer proximity to heat-generating elements of an RF antenna system is presented. The RF aperture coldplate has a front side and a rear side. The RF aperture coldplate includes waveguides each forming an opening therethrough from the front side to the rear side, and passages substantially around the waveguides. The passages are configured to conduct cooling medium around the waveguides and between the front side and the rear side of the RF aperture coldplate.

Abstract: A terahertz interaction circuit is provided. The terahertz interaction circuit includes a waveguide and an electron beam tunnel. The waveguide has a folded shape and in which an electromagnetic wave propagates. The electron beam tunnel is formed to penetrate through the waveguide. An electron beam passes through the electron beam tunnel. The waveguide includes a ridge portion in which a portion of a surface of the waveguide protrudes into the waveguide.

Abstract: Apparatus and methods for analyzing single molecule and performing nucleic acid sequencing. An integrated device includes multiple pixels with sample wells configured to receive a sample, which, when excited, emits radiation; at least one element for directing the emission radiation in a particular direction; and a light path along which the emission radiation travels from the sample well toward a sensor. The apparatus also includes an instrument that interfaces with the integrated device. Each sensor may detect emission radiation from a sample in a respective sample well. The instrument includes an excitation light source for exciting the sample in each sample well.

Abstract: According to various aspects, exemplary embodiments are disclosed of antenna assemblies and methods of manufacturing the same. In an exemplary embodiment, a method generally includes forming (e.g., molding, etc.) a sleeve over and/or between a first portion of a first component (e.g., a bushing, etc.) and a second portion of a second component (e.g., adaptor, etc.). The sleeve is coupled to the first and second portions of the respective first and second components. The method may also include removably attaching an antenna connector subassembly to the first component such that a printed circuit board assembly of the antenna connector subassembly is covered by the sleeve. The method may additionally include overmolding a sheath over the sleeve and one or more radiating elements of a multiband antenna assembly that includes the antenna connector subassembly, whereby the sleeve covers and protects the printed circuit board assembly during the overmolding.

Abstract: The disclosure discloses a wide-frequency wave-absorbing metamaterial, which comprises a plurality of layers of substrates and microstructures respectively arranged on the substrates at different layers. The wave-absorbing frequency band of the wide-frequency wave-absorbing metamaterial is relatively wide. The disclosure further discloses an electronic device and a method for obtaining a wide-frequency wave-absorbing metamaterial. By using the foregoing manner, the disclosure can enable a wave-absorbing metamaterial to significantly increase a wave-absorbing bandwidth based on a relatively good electromagnetic wave absorbing effect.

Abstract: In a smart card having an antenna structure and a metal layer, an insulator layer is formed between the antenna structure and the metal layer to compensate for the attenuation due to the metal layer. The thickness of the insulator layer affects the capacitive coupling between the antenna structure and the metal layer and is selected to have a value which optimizes the transmission/reception of signals between the card and a card reader.

Abstract: A radio device housing uses an exterior layer or surface made of an electrically conductive anti-static material that is formed over an interior or inner layer that is made of a non-conductive material. The anti-static material prevents the accumulation of static charge on the device housing in accordance with intrinsically safe design standards. An antenna portion is formed on a section of the non-conductive material that is not covered by the conductive material. An antenna element is disposed on the antenna portion and coupled to a radio circuit inside the device.

Abstract: Apparatus and methods for enhanced antenna port isolation are disclosed. In one embodiment, a spatially compact patch antenna apparatus is disclosed. A plurality of walls are incorporated into the antenna assembly's bottom cover. The walls are located under the radiating element located on a top cover of the antenna assembly. The walls are in one implementation oriented orthogonally with respect to one another, and are placed adjacent to respective antenna feeds. The walls are then at least partly metallized using, for example, a laser direct structuring (LDS) process, and are further connected to a ground plane of an external substrate. By incorporating the metallized wall structures on the existing plastic structure of the bottom cover, isolation between the antenna ports is improved without requiring installation of additional components, use of slots in the ground plane, or increased physical separation (i.e., distance). Manufacturing cost and consistency are also advantageously improved.

Abstract: A UHF-RFID antenna having a central segmented loop surrounded by passive dipole structures provides shaping of the electric and magnetic fields to reduce the number of false positive reads by a UHF-RFID reader at a point of sale.

Abstract: An antenna module and a manufacturing method for the same are disclosed. With the miniaturization trend for mobile communication terminals, the invention can achieve the miniaturization of antenna modules and facilitate the design of the antenna. The SMD as a matching component for given resonance frequency and impedance matching of the antenna is mounted on the antenna module to make the antenna module compact, and functions as a matching circuit for impedance matching to facilitate the design of mobile devices.

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 device disclosed herein includes a tubular member which is flexible and configured to receive ultraviolet (UV) light from a UV illumination coupler. The tubular member contains a lumen defining a longitudinal interior space within the tubular member, a tubular body bounded by an inner wall defining an outer boundary of the lumen and an outer wall defining an outer surface of the tubular member, at least one optical fiber disposed outside of the interior space not parallel to an axis of the lumen and adapted to receive the UV light from the UV illumination coupler, and a protective component adapted to prevent substantively all of the UV light emitted from the optical fiber from exiting the outer wall. Methods for producing and using such devices are also disclosed herein.

Abstract: A method of manufacturing an antenna pattern frame, includes arranging antenna radiators in an elongated radiator sheet in the form of cells, the antenna radiators including antenna pattern portions receiving an external signal, and while moving the radiator sheet, forming connection terminal portions of the antenna radiators by a successive bending process and injecting-molding radiator frames such that the antenna pattern portions are formed on one set of respective sides of the radiator frames and the connection terminal portions are formed on the other set of respective opposite sides of the radiator frames.

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.