| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 343870000 | With connector or terminals | 15 |
| 20110050535 | ANTENNA, ANTENNA UNIT, AND COMMUNICATION DEVICE USING THEM - An antenna has a base substrate | 03-03-2011 |
| 20110050536 | Low-Profile Tunable Wide-Range Loop-Slot Antenna - The Loop-Slot Antenna design provides a large range of tunable frequencies for transceiving while maintaining a small profile perfect for mounting on vehicles or other objects where a large antenna is impractical or infeasible. As compared with known vertical polarization antennas that have considerable height, for instance quarter-wave and half-wave vertical stubs of h=λ/4 or h=λ/2, the antenna of this invention has height of h=λ/100. | 03-03-2011 |
| 20110267254 | RFID TRANSPONDER ANTENNA - An RFID transponder antenna has a carrier substrate and an auxiliary substrate. The carrier substrate is provided with a contact point for a first connection to an integrated circuit, and a first conductor path including at least two coil turns. A first end of the path forms a contact terminal for a second connection to the integrated circuit. The other end forms a connection point for an electrical connection to a second conductor path. The second path on the auxiliary substrate forms a bridge over the coil turns. The second conductor path has one end connected to the contact point, and another end connected to the connection point providing a permanent connection between the auxiliary substrate and/or the first conductor path, and the carrier substrate and/or second conductor path; the permanent connection being formed at least at one point lying between both ends of the auxiliary substrate. | 11-03-2011 |
| 20120162043 | MULTIBAND ANTENNA - A multiband antenna includes a feed unit, a first transceiving unit, a second transceiving unit, and a resonance unit. The first transceiving unit and the second transceiving unit cooperatively form a loop. When feed signals are input to the feed unit, the feed signals are respectively transmitted through the first transceiving unit and the second transceiving unit to enable the first transceiving unit and the second transceiving unit to respectively receive and send wireless signals of different frequencies, and the resonance unit is driven to resonate and cooperate with the first transceiving unit and the second transceiving unit to respectively form additional antenna members, such that the multiband antenna is capable of receiving and sending wireless signals in more than two frequency bands. | 06-28-2012 |
| 20130135173 | MULTIBAND LOOP ANTENNA - An approximately planar antenna assembly can be formed or used, such as comprising a printed circuit board assembly. In an example, the approximately planar antenna assembly can include a dielectric material and a conductive loop comprising an outer loop portion having a first conic section an inner loop portion having a second conic section located within a footprint of the first conic section. The planar antenna assembly can be configured to support wireless transfer of information in at least two ranges of operating frequencies, such as two or more respective ranges used for cellular communications. | 05-30-2013 |
| 20130201074 | A LOOP ANTENNA FOR MOBILE HANDSET AND OTHER APPLICATIONS - There is disclosed a loop antenna for mobile handsets and other devices. The antenna comprises a dielectric substrate ( | 08-08-2013 |
| 20140002325 | ELECTRODE MEMBER, ANTENNA CIRCUIT AND IC INLET | 01-02-2014 |
| 20150303570 | LOOP ANTENNA FOR MOBILE HANDSET AND OTHER APPLICATIONS - There is disclosed an antenna system for mobile handsets and other devices. The antenna system comprises a dielectric substrate having first and second opposed surfaces, a conductive track on the substrate, and a separate, directly driven antenna to drive the parasitic loop antenna formed by the conductive track. Two grounding points are provided adjacent to each other on the first surface of the substrate, with the arms of the conductive track extending in generally opposite directions from the grounding points. The conductive tracks then extend towards an edge of the dielectric substrate, before passing to the second surface of the dielectric substrate and then passing across the second surface of the dielectric substrate following a path generally following the path taken on the first surface of the dielectric substrate. The conductive tracks then connect to respective sides of a conductive arrangement formed on the second surface of the dielectric substrate that extends into a central part of a loop formed by the conductive track on the second surface of the dielectric substrate. | 10-22-2015 |
| 20150349400 | SENSOR TAG AND MANUFACTURING METHOD FOR SENSOR TAG - A sensor tag ( | 12-03-2015 |
| 20160056538 | WIRELESS COMMUNICATION APPARATUS AND NFC ANTENNA STRUCTURE - A wireless communication apparatus includes an electronic device and an NFC antenna structure having a sheet and an antenna disposed on a surrounding area of the sheet. The antenna has an outer connecting pad, an inner connecting pad, and a radiating body. The outer and inner connecting pads are respectively arranged adjacent to the outer and inner edges of the surrounding area. The radiating body has a continuously spiral shape, and two ends of the radiating body are respectively connected to the outer and inner connecting pads. The radiating body is extended from the outer connecting pad to spirally travel on the surrounding area and forms at least three loops. The outer and inner connecting pads of the antenna respectively and detachably abut against the two pins of the electronic device to achieve electrical connection between the electronic device and the antenna of the NFC antenna structure. | 02-25-2016 |
| 20160126615 | NFC ANTENNA ASSEMBLY AND MOBILE COMMUNICATION DEVICE COMPRISING THE SAME - A NFC antenna assembly and a mobile communication device are provided. The NFC antenna assembly including: a shell, a connecting device and an antenna circuit, the connecting device includes a female connector and a male connector configured to connect with the female connector via a snap-fit connection, and the antenna circuit formed on the shell and the male connector and defining first and second ends which are adapted to electrically connect with the female connector via the male connector. | 05-05-2016 |
| 20160181698 | ANTENNA ELEMENT, ANTENNA DEVICE, AND WIRELESS COMMUNICATION EQUIPMENT USING THE SAME | 06-23-2016 |
| 20160190692 | Flexible RFID Antenna - An RFID antenna for a POS device has a slender, single-sided, flexible substrate with a first end and a second end. Multiple conductors extend along the substrate, from the first end to the second end. A flexible covering layer is attached to the substrate and covers the conductors. The substrate is wrapped to superimposed the ends of the substrate. A connector connects the ends of the conductors on the first end of the substrate to the ends of the conductors on the second end of the substrate whereby the plurality of conductors form an antenna in the form of a continuous helical coil. | 06-30-2016 |
| 20160190693 | HYBRID-TYPE NFC ANTENNA AND THE ELECTRONIC DEVICE THEREOF - A hybrid-type near field communication (NFC) antenna utilized in an electronic device is provided. The hybrid-type NFC antenna includes two differential connection ports and a loop antenna device. The two differential connection ports are respectively coupled to two differential outputs of a radio frequency circuit of the electronic device. The loop antenna device is connected between the two differential connection ports, wherein the loop antenna device includes at least one first metal component, and an inductance of the loop antenna device is greater than a first inductance; and wherein the at least one first metal component is a metal element or an antenna device of the electronic device. | 06-30-2016 |
| 20160190694 | FLEXIBLE RFID ANTENNA - An RFID antenna has a flexible single-sided substrate including a first end, a second end and a leading-out terminal. A plurality of parallel conductors are provided on the substrate and extend between the first end and the second end of the substrate. One of the multiple conductors is broken at the leading-out terminal and extends to an end of the leading-out terminal to form a connection terminal. A flexible covering layer is attached to the substrate and covers the conductors. Ends of the conductors on the first end of the substrate are respectively connected to ends of the conductors on the second end of the substrate to form a helical RFID coil. | 06-30-2016 |
