Two input/output terminals are provided on a lower surface of an RFIC element. An antenna element includes an elastic material and connecting portions respectively connected to the two input/output terminals of the RFIC element, a loop that includes the connecting portions, and open-ended linear antenna portions that define and function as radiators. The line width of the loop is greater than that of each of the linear antenna portions.

A fastener with a head element that is coupled to a strip element is disclosed. The strip element is configured to fasten to the head element via an attachment structure of the head element. An identification device is molded into the fastener. The identification device has an identifier integrated circuit (IC) within an IC package and an antenna, having a portion internal to the IC package and a portion extending out of the IC package, coupled to the identifier IC.

An antenna comprises: a first terminal; a second terminal; and a winding, having an inductance, comprising a plurality of turns and connected between the first and second terminals such that a change in magnetic flux linking the winding generates a corresponding voltage between said terminals. The winding comprises a conductive element connected to the first and second terminals and extending around said turns from the first terminal to the second terminal and having a thickness not exceeding Xμm along a length of the conductive element from the first to the second terminal and a width not exceeding Xμm along said length, where X is less than or equal to 10, whereby said conductive element is substantially non-visible to a naked human eye.

An electromagnetic-coupling dual IC card includes an IC module and a plate-like card body. The IC module includes a module substrate having a first surface and a second surface, contact terminals provided on the first surface of the module substrate to be contactable with an external contact-type device, an IC chip having a contact communication function and a contactless communication function and disposed on the second surface, and a first connecting coil provided on the first surface. The plate-like card body includes an antenna sheet embedded therein and has a recess for holding the IC module, the antenna sheet being provided with a coupling coil to be electromagnetically coupled to the first connecting coil, and a main coil connected to the coupling coil to perform contactless communication with an external contactless-type device. The first connecting coil does not overlap with the contact terminals in plan view.

The disclosure relates to a device for wirelessly transmitting and receiving data of an RFID tag introduced in an electromagnetically shielded housing, wherein a transmission region is provided in the housing wall of the housing and wherein a transceiver connected to the RFID tag is also provided, which transceiver is configured to transmit and/or receive data from the RFID tag through the transmission region, wherein a double coil formed by two coil assemblies is provided directly above or below the transmission region for coupling to an external receiving unit of a reading device and for coupling to the transceiver.

A noncontact communication medium includes an antenna coil that is formed on a substrate having a through-hole and induces power with application of a magnetic field from an outside, and a processing circuit that operates using the power induced by the antenna coil. The processing circuit is inserted in the middle of the antenna coil. The antenna coil is wound in a loop shape along an outer periphery of the substrate. An outer peripheral end of the antenna coil is connected to the through-hole. A portion of the antenna coil on the substrate facing a position of the through-hole has a shape recessed to an inner peripheral side of the antenna coil in a winding direction.

A noncontact communication medium comprises an antenna coil that is formed in a substrate and induces power with application of a magnetic field from an outside, and a processing circuit that operates using the power induced by the antenna coil. The substrate has a plurality of layers in a thickness direction. The antenna coil is wound in a loop shape in a first layer among the plurality of layers. One end and the other end of the antenna coil are electrically connected through an auxiliary antenna coil wound in a loop shape in a second layer different from the first layer among the plurality of layers. At least one of the first layer or the second layer is buried in the substrate.

An RFID module is disposed at a position where the RFID module is electromagnetically coupled to the conductor. An RFIC receives power induced by receiving an electromagnetic wave for power reception to output a transmission signal. A power reception coupling unit is electromagnetically coupled to the conductor to receive power. A transmission coupling unit is electromagnetically coupled to the conductor to output a transmission signal to the conductor.

Described is an antenna comprising two oppositely wound antenna coils, each antenna coil formed by concentric conductor coils. An outermost conductor coil of one antenna coil is conductively connected to an outermost conductor coil of the other antenna coil via a shared conductive portion. An innermost conductor coil of each antenna coil terminates in a bridge connector, and a bridge conductively links the bridge connectors.

Described examples relate to a radio frequency identification (RFID) device configured to be detachably coupled to an object. The RFID device may include a first RFID tag comprising a first antenna, the first antenna comprising a first arcuate element and a second arcuate element, wherein the first accurate element and second arcuate element are arranged in a semicircle. The RFID device may also include a second RFID tag comprising a second antenna.