An RFIC device including a resin block having a first surface, a second surface that faces the first surface, and a through-hole that extends through the first surface and the second surface. Moreover, the RFIC device includes an RFIC element that is embedded in the resin block and a coil antenna disposed in the resin block that is connected with the RFIC element and that has a central axis that extends from the first surface to the second surface. In addition, the through-hole extends inside the coil antenna.

A metal cap is provided with an RFID tag that includes a metal cap including a cylindrical main body part, a top plate part formed at one end of the cylindrical main body part, and an opening part formed at the other end of the cylindrical main body part, and an RFID tag disposed on the metal cap. The RFID tag includes an RFIC element disposed in the metal cap, and a loop antenna connected to the RFIC element. At least a portion of a loop opening of the loop antenna extends in a circumferential direction R of the metal cap while being exposed from an opening edge of the opening part of the metal cap to the outside of the metal cap.

The system and techniques disclose herein describe a radio-frequency identification (RFID) capacitance liquid measurement and tag (RCLMT) system for detecting a volume of liquid in a container (liquid level detection), for example an amount of wine inside of a wine bottle. The RCLMT system includes a RFID chip, flexible printed circuit board (PCB), capacitive strips, and adhesive which implements a RFID tag-based sensor that advantageously uses low power and has low cost. Further, a user platform, including the RCLMT system and computer software applications (apps) and a backend system (e.g., cloud service) is described herein. The RCLMT system acts as a passive liquid level detection sensor, which enables the amount of a liquid beverage, such as alcohol, that is inside of a container to be automatically and accurately ascertained.

A metal chip card capable of supporting radio frequency communication and payment. An antenna circuit module of the metal chip card consists of an FPC/PCBA antenna circuit board (11), an IC chip (12), a chip sealing adhesive (13), and a two-side gold-plated touch electrode (26). An ultrathin ferrite wave absorption electromagnetic shielding layer (27) is stuck below the antenna circuit module, and the antenna circuit module and a substrate (28) which is provided with a milled groove and the inner wall of which is coated with a hot melt adhesive layer (14) are packaged into a metal chip card by means of hot pressing. The metal chip card can implement RFID and NFC radio frequency functions on a metal card body and can be normally used without barriers.

An attention tag for a retail article that includes a label having an adhesive region bonded to a retail article and a protruding region that protrudes from the retail article when the label is attached thereto. Moreover, an RFID tag is disposed on the label and includes an RFIC element and an antenna pattern including first and second antenna portions that are respectively connected to first and second ends of the RFIC element. Moreover, the first antenna portion is disposed in the protruding region of the label while the second antenna portion of the RFID tag is disposed in the adhesive region of the label at a position facing a portion of the retail article.

An RFID tag is provided that includes a substrate, an RFIC element and a dipole antenna. The dipole antenna includes a first dipole element and a second dipole element. The first dipole element includes a first fold-back portion, and forms a capacitance between the first fold-back portion and a first facing portion. Furthermore, the first dipole element includes a first interposed portion that is interposed between a first open end and the second dipole element. Similarly, the second dipole element includes a second fold-back portion, and forms a capacitance between the second fold-back portion and a second facing portion. Furthermore, the second dipole element includes a second interposed portion that is interposed between a second open end and the first dipole element.

The invention relates to a contactless chip card intended to communicate with a chip card reader operating at a resonant frequency F.sub.0. The chip card includes a booster antenna provided with an inductive main antenna U and with an inductive concentrator antenna L.sub.2, which antennae are connected in series or parallel with a capacitor C, wherein the inductances of L.sub.1 and L.sub.2 and the capacitance of C are chosen on the one hand to obtain a resonant frequency F.sub.0 that is far enough from the frequency of the signal emitted by the reader to limit radiofrequency communication with the reader, and on the other hand so that the connection in parallel of a predetermined capacitance C.sub.d brings the resonant frequency of the card into the vicinity of said frequency F.sub.0 of the signal emitted by said reader.

A method begins by a first radio frequency identification (RFID) sensor, that is associated with a first object element, receiving a first data request signal from an RFID reader and sending a first radio frequency (RF) signal that includes first data to the RFID reader in response to the first data request signal. The method continues with a second RFID sensor receiving a second data request signal from, and sending second data to, the RFID reader. The method continues with the RFID reader sending a representation of the first and second data to a data processing unit, which processes the representation of the first and second data to determine a first and second data point regarding first and second object elements. The method continues by the data processing unit processing the first and second data points to determine an environmental relationship between the first and second object elements.

An insert for a chip card includes a body provided with a cavity in which is inserted an electronic module provided with a microelectronic chip connected to an inductive or capacitive coupling. The body has a stack of layers at least a first layer of which comprises a first booster antenna and a second layer of which comprises a second booster antenna, the various booster antennas being coupled together inductively and/or capacitively, and at least one of the booster antennas being coupled inductively and/or capacitively with the coupling of the module. The body furthermore comprises at least one metal plate disposed between two layers of ferrite, the first and second booster antennae and the metallic plate being arranged in such a way that at least one of the two booster antennas and the electronic module remain coupled together inductively and/or capacitively, despite the presence of the metal plate.

A tuning assembly for an RFID chip includes an input port, a control unit, and a plurality of capacitors connected in parallel between the input port and the control unit. A selector circuit is coupled to each capacitor and to the control unit and is configured to selectively allow and prevent current flow through any of the capacitors in response to commands from the control unit, thereby adjusting the capacitance of the RFID chip. The commands include a command to always allow current flow through a capacitor, another command to always prevent current flow through a capacitor, and a third command to selectively allow and prevent current flow through a capacitor (e.g., for automatic adjustment of the capacitance of the RFID chip). The control unit may be programmed before or after the RFID chip is coupled to an antenna, including after a fully assembled RFID label has been attached to an article.