Systems and methods for integrating tags with items. The methods comprise: dynamically determining a length of each metal thread to be incorporated into or trace to be disposed on a item to optimize tag performance in view of dielectric and tuning properties of the item. In the metal thread scenarios, the methods also involve: creating a metal thread having the length that was dynamically determined; and sewing the metal thread into the item being produced to form an antenna for a first tag. In the trace scenarios, the methods also involve forming the trace on the item being produced to form an antenna for a first tag. Next, at least a communications enabled device is attached to the item so as to form an electrical coupling or connection between the communications enabled device and the at least one antenna.

A method of using shielded straps with RFID tag designs is disclosed. Specifically, the RFID device, in one embodiment, comprises a bridge conductor which couples the antenna and pair of strap pads together. Thus, the coupling between the bridge conductor and the strap conductor, the coupling between the bridge conductor and the antenna conductor, and the coupling between the antenna conductor and the strap conductor increases the total capacitance of the RFID strap device. Further, the presence of the bridge conductor also reduces the area occupied for a given inductance, and provides a higher effective capacitance when the bridge strap is connected to the antenna.

An RFIC module is provided that includes an RFIC and an impedance matching circuit connected to an RFIC side first terminal electrode, an RFIC side second terminal electrode, an antenna side first terminal electrode and an antenna side second terminal electrode. The impedance matching circuit includes a first inductor, a second inductor, a third inductor, and a fourth inductor, and a conductor pattern that configures the first inductor, the second inductor, the third inductor, and the fourth inductor as a single coil-shaped pattern.

The invention relates to a capacitive, planar information carrier with a first, second and third electrically conductive area wherein the first electrically conductive area is overprinted with a first dielectric layer having a first relative permittivity ε1 and wherein the third electrically conductive area is overprinted with a second dielectric layer having a second relative permittivity ε2. In another aspect, the invention relates to an information carrier formed from an electrically conductive surface of an object or an electrically conductive object. In other aspects, the invention relates to methods for the manufacture of information carriers, methods for detecting information carriers and to the use of an information carrier.

The embodiments of the present invention are an RFID device including an RFID tag, an antenna, and a programmable logic. The RFID tag is inside a custom screw of an eyeglass frame configured to track and identify the eyeglass frame. The antenna is inside the custom screw of the eyeglass frame configured to receive a transmitted signal to collect and power the RFID tag. The programmable logic is inside the custom screw of the eyeglass frame configured to process and store transmission and sensor data. Barcodes are eliminated because a person using a barcode reader has the burden of scanning every item one-by-one, and assuring that the tag is within the line of sight of the reader.

Systems and methods for integrating tags with items. The methods comprise: dynamically determining a length of each metal thread to be incorporated into or trace to be disposed on a item to optimize tag performance in view of dielectric and tuning properties of the item. In the metal thread scenarios, the methods also involve: creating a metal thread having the length that was dynamically determined; and sewing the metal thread into the item being produced to form an antenna for a first tag. In the trace scenarios, the methods also involve forming the trace on the item being produced to form an antenna for a first tag. Next, at least a communications enabled device is attached to the item so as to form an electrical coupling or connection between the communications enabled device and the at least one antenna.

Systems and methods for integrating tags with items. The methods comprise: dynamically determining a length of each metal thread to be incorporated into or trace to be disposed on a item to optimize tag performance in view of dielectric and tuning properties of the item. In the metal thread scenarios, the methods also involve: creating a metal thread having the length that was dynamically determined; and sewing the metal thread into the item being produced to form an antenna for a first tag. In the trace scenarios, the methods also involve forming the trace on the item being produced to form an antenna for a first tag. Next, at least a communications enabled device is attached to the item so as to form an electrical coupling or connection between the communications enabled device and the at least one antenna.

Systems and methods for integrating tags with items. The methods comprise: turning a reel by an amount that allows a portion of an elongate narrow substrate that includes a first tag of a plurality of tags to be paid out (where each of the plurality of tags comprises at least one antenna formed of a trace or wire disposed on the elongate narrow substrate and a communication enabled device coupled to the elongate narrow substrate so as to have an electrical coupling or connection with the at least one antenna); dynamically tuning the first tag to optimize tag performance in view of dielectric and tuning properties of a first item being fabricated; cutting the elongate narrow substrate so as to cause the first tag to be placed on the first item being fabricated; and coupling the first tag to the item being fabricated.

A method of detecting a stimulus can include detecting an output from a radio frequency identification tag including a sensor. A smartphone-based sensing strategy can use chemiresponsive nanomaterials integrated into the circuitry of commercial Near Field Communication tags to achieve non-line-of-sight, portable, and inexpensive detection and discrimination of gas phase chemicals (e.g., ammonia, hydrogen peroxide, cyclohexanone, and water) at part-per-thousand and part-per-million concentrations.

Systems and methods for integrating tags with items. The methods comprise: dynamically determining a length of each metal thread to be incorporated into or trace to be disposed on a item to optimize tag performance in view of dielectric and tuning properties of the item. In the metal thread scenarios, the methods also involve: creating a metal thread having the length that was dynamically determined; and sewing the metal thread into the item being produced to form an antenna for a first tag. In the trace scenarios, the methods also involve forming the trace on the item being produced to form an antenna for a first tag. Next, at least a communications enabled device is attached to the item so as to form an electrical coupling or connection between the communications enabled device and the at least one antenna.